Abstract
Aldosterone-producing adenomas (APAs) are the commonest curable cause of hypertension. Most have gain-of-function somatic mutations of ion channels or transporters. Herein we report the discovery, replication and phenotype of mutations in the neuronal cell adhesion gene CADM1. Independent whole exome sequencing of 40 and 81 APAs found intramembranous p.Val380Asp or p.Gly379Asp variants in two patients whose hypertension and periodic primary aldosteronism were cured by adrenalectomy. Replication identified two more APAs with each variant (total, n = 6). The most upregulated gene (10- to 25-fold) in human adrenocortical H295R cells transduced with the mutations (compared to wildtype) was CYP11B2 (aldosterone synthase), and biological rhythms were the most differentially expressed process. CADM1 knockdown or mutation inhibited gap junction (GJ)-permeable dye transfer. GJ blockade by Gap27 increased CYP11B2 similarly to CADM1 mutation. Human adrenal zona glomerulosa (ZG) expression of GJA1 (the main GJ protein) was patchy, and annular GJs (sequelae of GJ communication) were less prominent in CYP11B2-positive micronodules than adjacent ZG. Somatic mutations of CADM1 cause reversible hypertension and reveal a role for GJ communication in suppressing physiological aldosterone production.
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Main
Primary aldosteronism (PA) is a common cause of hypertension and is surgically curable when it is a consequence of an aldosterone-producing adenoma (APA) in one of the adrenal glands1. Whereas physiological adrenal secretion of aldosterone is regulated by (and inversely related to) salt intake, the autonomous aldosterone production by APAs is due to hallmark somatic mutations2,3. Pathogenic KCNJ5 variants have the highest apparent prevalence in most cohorts of PA patients except African Americans4,5. However, these KCNJ5 variants are usually found in relatively large APAs6, which are the easiest to recognize radiologically, but whose cells paradoxically resemble the cortisol- rather than aldosterone-secreting zone of the normal adrenal gland7. APAs with pathogenic CACNA1D, ATP1A1 and ATP2B3 variants are typically smaller than KCNJ5-mutant APAs and resemble the physiological aldosterone-secreting cells of the adrenal zona glomerulosa (ZG)8,9,10. These smaller, ZG-like APAs are often overlooked on a CT scan, or considered equivocal on routine adrenal pathology. However, once a specific antibody for CYP11B2 (aldosterone synthase) became available, as ex vivo ligand, their identity and frequency were readily confirmed, and an inverse correlation between signal and size became apparent8,10,11,12,13. Their radiological recognition was facilitated by the development of dexamethasone-(11C)-metomidate and (18F)-chloro-2-fluoroethyletomidate PET-CT as in vivo ligands for CYP11B2 (refs. 14,15,16). We, therefore, wished to determine whether CYP11B2-dense small APAs have new mutations and whether (depending on patient demography and ascertainment) KCNJ5-mutant APAs may now be outnumbered by other genotypes. Whole-exome sequencing (WES) of sequential APAs indeed found only nine with pathogenic KCNJ5 variants versus 22 with other genotypes. These included a new combination of GNA11 and CTNNB1 variants, whose discovery, replication and phenotype have been separately reported17. A further APA had a somatic mutation of the cell adhesion molecule 1 (CADM1) gene. Herein we report the phenotype and replication of this mutation in other cohorts. Studies of CADM1 function in other tissues18,19,20,21, and the discovery of deleterious mutation in APAs, led us to several unsuspected pathways of aldosterone regulation. Of these, we concentrated on gap junction (GJ)-dependent regulation of aldosterone production. As cell–cell communication in adrenal ZG is considered critical for regulating aldosterone production22,23,24,25,26, we hypothesized that the link between cell–cell interaction and aldosterone production may be through GJs, which form only when the two hemichannels of GJ (called connexons) on apposed cells come together27,28. Our hypothesis was prompted by the suppression of GJ intracellular communication (GJIC) and increased production of glucagon that follow the silencing of CADM1 in pancreatic islet cells18.
Results
WES of 40 APAs identifies a new CADM1 somatic mutation
WES was performed in 40 APAs from predominantly European ancestry patients with PA (Supplementary Table 1). The APAs were consecutive, except for two that antedated our previous WES (n = 13)8 and two that were excluded by prior targeted sequencing; 31 had a known aldosterone-driver somatic mutation, including 11 CACNA1D and nine KCNJ5 variants (Supplementary Tables 1 and 2). A small (13 × 7 mm) APA, with dense CYP11B2 expression, had a new mutation in the intramembranous portion of CADM1 (P1 of Fig. 1a–c, Extended Data Fig. 1 and Supplementary Table 3). The only prior association of CADM1 with aldosterone synthesis was as one of the transcripts upregulated in APAs29. All known somatic mutations and the new mutation in CADM1 were confirmed by Sanger sequencing. The likely relevance of the CADM1 variant was apparent from its intramembranous position and SIFT score of 0, suggesting a deleterious substitution. The resected adrenal showed the typical features of a ZG-like APA on histopathology (Extended Data Fig. 1a). Immunohistochemistry (IHC) showed dense membranous staining of CADM1 both in areas staining strongly for CYP11B2 and in the adjacent ZG and adrenal medulla (Extended Data Fig. 1b,c), supporting previous reports of twofold to fourfold upregulation of CADM1 RNA expression in ZG and APAs compared to zona fasciculata (ZF)29,30,31.
Discovery of recurrent CADM1 somatic mutations in APAs
Initial search for further examples of CADM1 variants was undertaken by Sanger sequencing. Fifty-three APAs, negative for known variants in previous targeted sequencing studies, were sourced from four centers in the UK and Japan. No pathogenic CADM1 variants were found in these. We then re-interrogated a previous WES of 81 APAs from a German cohort, in which no gene with recurrent somatic mutations had been found, other than those previously reported (Supplementary Table 4). One of the 81 APAs had a CADM1 somatic mutation, p.Gly379Asp, altering the adjacent residue to the one altered in the index case (P2 of Fig. 1b,c). Patients P1 and P2 were both males in their forties whose resistant hypertension was cured by adrenalectomy (Table 1). Both appeared to have episodic hyperaldosteronism, detected by serial aldosterone (Aldo) and renin measurements that identified variable diagnostic aldosterone-renin ratios (ARR).
Further investigation by targeted sequencing of 43 APAs without known aldosterone-driver mutations from a French cohort identified three further cases, one with p.Val380Asp and two with p.Gly379Asp variants in CADM1 (P3–P5 of Fig. 1c and Table 1). Finally, a sixth case was discovered by targeted sequencing of 200 APAs in a US cohort, harboring the p.Val380Asp variant (P6 of Table 1). The range of prevalence of the CADM1 variants is between 0.5% and 1.0% (Supplementary Table 4), with 0.93% in the largest cohort harboring three variants.
IHC of the available APAs showed strong staining for CYP11B2 and weak staining for CYP11B1, supporting a ZG-like APA histopathology (Extended Data Fig. 2a,b). IHC of these APAs also found dense membranous staining of CADM1 similar to the index case (Extended Data Fig. 2c). Taken together with the finding of the mutation in the cDNA of the index APA (P1 of Fig. 1c), the consequences of these CADM1 variants appear due to expression of an abnormal protein rather than an absence of expression, as occurs in some malignant tumors32.
Functional analyses of CADM1 variant in human adrenal cells
CADM1 has been known by various names, each reflecting an aspect of its function, such as synaptic cell adhesion molecule (SynCAM1) and immunoglobulin superfamily member 4 (IGSF4)32,33,34,35,36. The immunoglobulin ectodomains pair with those of adjacent cells, but can also—like those of many single transmembrane (TM) domain proteins—be shed, by ADAM10, and maybe ADAM17 (ref. 19). Isoforms of CADM1 vary in susceptibility to shedding20, with the 11 residues of exon 9 providing a nonglycosylated ‘stalk’ facilitating access to the sheddase. The two isoforms established by reverse transcription PCR (RT–PCR) and sequencing to be most abundant in human adrenal, both in APA and adjacent cortex, are encoded by 10 or 11 of the full-length 12 exons (442 and 453 amino acids; Supplementary Fig. 1). In most of the analyses performed, both isoforms of both variants were studied.
To determine whether the mutations in CADM1 influence aldosterone production, human adrenocortical H295R cells were transduced with wild-type (WT), mutant or sh-CADM1 (Fig. 2a–c). It was interesting to note that human embryonic kidney HEK293T cells (used for lentivirus production) transfected with WT CADM1 appeared in clusters, while a more uniform monolayer of cells was observed in cells transfected with empty vector (EV) and mutant CADM1 (Fig. 2a). Cells transduced with mutant CADM1 increased expression of CYP11B2, assessed by quantitative PCR (qPCR), by 10- to 24-fold (Fig. 2d), which is many times larger than the typical effect of aldosterone-driver mutations in ion channels or transporters37,38,39,40. The enhanced expression of CYP11B2 was paired with an increase in aldosterone production, although of smaller magnitude (2- to 4-fold) than that of the enzyme (Fig. 2e). Conversely, silencing of CADM1 reduced both aldosterone secretion and expression of CYP11B2 (Fig. 2d,e).
Protein modeling predicts effects on the tertiary structure
The shed ectodomains (or a secreted, truncated isoform) can compete with the intact ectodomains and regulate the role of CADM1 in adhesion41. Intracellular actions are also important. Either the remnant C-terminal fragment (CTF), after shedding and further cleavage by γ-secretase, can traffic to and activate pathways within cell organelles (for example nucleus, mitochondria)19,42,43, or CADM1 may be activated by dimerization at the TM domain44,45. Indeed, the mutations we found lie within the key AviGGvia motif predicted to be the dimerization site in a cluster of 11 single TM domain proteins44. Western blots of various cell types transfected with WT or mutant CADM1 were undertaken to investigate the effects of the mutations on ectodomain shedding. Mouse 3T3 cells were studied initially as they lack native CADM1. The variants of both isoforms caused substantial loss of full-length CADM1, attributable in part to increased shedding, as evidenced by increased N-terminal fragments (NTF) in the cell medium (Supplementary Fig. 2a). There was no definite increase in CTFs, and the clearest difference was a decrease in their size. No γ-secretase products could be detected.
Transfected human adrenocortical (H295R) cells showed less difference than 3T3 cells between WT and mutant CADM1, except for the shorter CTF (Fig. 3a and Supplementary Fig. 2b,c). As their abundance was low compared to full-length CADM1, the interest in their smaller size arises from the following putative explanation. ADAM10 (and ADAM17) are intramembranous enzymes (sheddases) with an ectodomain that includes the active site. No consensus cleavage sequence is established for their substrates, which are cleaved at a defined distance outside the plasma membrane46,47. Because both enzyme and substrate are semifixed in position, the cleavage point may be determined by where the substrate meets the enzyme active site19. This point is predicted to be in close proximity to the membrane surface, ~10 to 20 residues beyond the TM domain (Fig. 3b), with the exact site depending on the angle of exit. A perpendicular ectodomain will be cut within fewer residues from the membrane than an angulated ectodomain, yielding a shorter CTF (Fig. 3c). Introduction of a charged, unpaired aspartic acid residue (G379D and V380D) in the hydrophobic lipid bilayer is likely to affect the tilt angle of the TM domain. Indeed, two independent molecular modeling exercises, based on structures of other single TM domain proteins, predicted a doubling of the angle, from 49o for WT to 90o for V380D (Fig. 3d,e and Supplementary Fig. 2d,e). In the first model, straightening of the TM domain was associated with the shortening of the mutant TM helix in dimers with WT CADM1 (Supplementary Fig. 2d). The second model found mutant homodimers to be straighter (more perpendicular to the membrane) than WT (Supplementary Fig. 2e).
CADM1 variants inhibit gap junction intercellular communications (GJICs)
Transcriptome analysis of laser-dissected cortical zones showed that GJA1 (encoding GJ alpha-1, formerly connexin 43) is the predominant GJ mRNA expressed in the human adrenal cortex, only threefold lower, on average, in ZG and APAs than in ZF (Supplementary Table 5a)31,48. The array data from a similar study showed the highest expression in ZF and zona reticularis, and twofold to threefold lower levels in ZG and aldosterone-producing micronodules (APMs, previously known as aldosterone-producing cell clusters or APCCs)49.
To explore whether CADM1 regulates GJ formation and communication, we studied the transfer between cells of a GJ-permeable dye calcein red, as a measure of GJIC. Transfer of calcein red was inhibited in cells transfected with mutant CADM1 (G379D or V380D; Fig. 4a,b and Supplementary Fig. 3a). Silencing of CADM1 also inhibited transfer (Fig. 4b and Supplementary Fig. 3b,c). Similar inhibition of dye transfer was obtained by soluble recombinant CADM1 ectodomains (Supplementary Fig. 3d,e; 16.7 ± 4.2% versus 38.9 ± 9.6% for Fc control, n = 5, P = 0.008 by Mann–Whitney U test)41. These three cases are consistent with the homophilic adhesion of CADM1 ectodomains enabling connexons of opposing cells to make contact. When homophilic adhesion is inhibited, whether by silencing, competition from recombinant ectodomains, or shedding of NTF (effectively equals ectodomains), GJIC is suppressed. However, the increased shedding of NTF from mutant CADM1 transfected into mouse cells (Supplementary Fig. 2a) was not seen in medium from variant-transduced H295R cells (Supplementary Fig. 2c). An alternative explanation for the inhibition of GJIC by CADM1 variants is that the predicted straightening of their ectodomains would push apposed cells beyond the reach of their connexons, which is an estimated maximum of 20–30 nm (Fig. 3d,e)50,51,52.
To show directly whether the inhibition of GJIC is due to failure of GJ channel formation, we made use of the dynamic GJIC process, which includes the internalization of a GJ plaque from two adjacent cells, followed by the formation of an annular GJ (AGJ) in one of the two cells comprising of GJ protein from both. This was done by labeling GJA1 with either the mApple or Venus fluorophores, and separate transfections of H295R cells with each of these constructs. Time-lapse of these cells cocultured together (Supplementary Video) found that GJ formation between adjacent cells (identified by co-expression of mApple and Venus fluorophores) was transient, and the formation of an AGJ was evidence of the brief encounter (Fig. 4c). To explore the effect of the CADM1 variants on GJ formation, GJA1-mApple cells were also cotransfected with GFP-labeled WT or mutant CADM1. In this experiment, only a minority of cells would express the three fluorophores (GFP, Apple and Venus)—those that (1) were double-transfected with CADM1-GFP and GJA1-mApple, (2) had come into contact with a GJA1-Venus transfected cell and (3) had the AGJ internalized in the double-transfected cell (Supplementary Fig. 3f). In the 24-h post-transfection images used for quantification, cell-contact had usually passed, leaving the triple-colored, AGJ-containing cells to be counted, as a proportion of all double-transfected cells. Such cells were more numerous with WT compared to mutant CADM1 transfection (Fig. 4d).
GJIC in physiological and pathological human adrenals
To quantify GJA1 expression in human adrenal ZG, and explore its anatomical relation to aldosterone-producing cells, we undertook laser capture microdissection for qPCR of GJA1 and zonal marker genes, and IHC of 15 adrenals, including our index case. Data from a previous microarray of 21 adrenals showed LGR5 and GSTA3 to be the most selective markers for ZG and ZF, respectively (Supplementary Fig. 4a,b)31,48. There was high expression of GJA1 in ZG and ZF relative to the expression of LGR5 and GSTA3 in each zone (Supplementary Fig. 4c). qPCR of RNA from a further three adrenals showed ZG expression of GJA1 to be, on average, a quarter of that in ZF (Extended Data Fig. 3a and Supplementary Fig. 4c).
On IHC with all relevant controls (Extended Data Fig. 3b and Supplementary Fig. 5a,b), GJA1 protein expression was variable in quantity and distribution. At most ZG regions, staining was punctate on or inside the plasma membrane, differing from the diffuse linear appearance in ZF (Extended Data Fig. 4 and Supplementary Fig. 5c). Staining with two different antisera was comparable, and absent when the primary antibody was omitted or competed by a specific peptide (Extended Data Fig. 3b and Supplementary Fig. 5b,c). A similar pattern of staining for GJA1 was seen on immunofluorescence. Because CYP11B2 itself is rarely expressed in adult human adrenal outside APMs, we used positive staining for VSNL1 and DAB2, and negative staining for CYP17A1, as markers of ZG (Supplementary Fig. 5d and Extended Data Fig. 5)7,13. On high-resolution microscopy, AGJs were visualized, and GJA1 punctate staining in ZG was seen on cell membranes (Fig. 5a, Extended Data Fig. 5 and Supplementary Fig. 5e). The presence of AGJ confirms the dynamic formation and internalization of GJs50,53. GJA1 intensity was also lower in APMs than in adjacent ZG (Extended Data Figs. 6 and 7 and Supplementary Fig. 6a–c). On semiquantification of GJA1 IHC, scored 0–3 by two independent pathologists in 14 adrenals from two cohorts, there was a rank order of GJA1 intensity as follows: ZF > ZI (zona intermedia) > ZG > APM (Supplementary Fig. 6d,e). GJA1 expression in APAs varied between tumors and between cell types, being sparse and punctate in CYP11B2-dense cells, and linear in foamy ZF-like cells (Supplementary Fig. 7a). A stabilizing partner of GJA1 is the tight-junction protein, TJP1, through its PDZ (postsynaptic density protein, Drosophila disc large tumor suppressor and zonula occludens-1 protein) domain54. We observed highly selective TJP1 expression in ZG (Supplementary Fig. 7b). By contrast, its expression was substantially reduced in APMs (Extended Data Fig. 7b and Supplementary Fig. 7c).
Modulation of GJIC regulates aldosterone production
Having demonstrated the presence of GJs in the ZG, we investigated the role of GJIC in aldosterone production. The connexin mimic peptide Gap27 targets the SRPTEKTIFFI sequence in GJA1 (ref. 55), and probably GJC1, which differs in protein sequence by just one amino acid residue. Treatment of angiotensin II (Ang II)-stimulated H295R cells with Gap27 increased CYP11B2 mRNA expression and aldosterone secretion by many fold, in a dose-dependent manner, the maximum response exceeding the 15- to 30-fold effect of transducing mutant CADM1 (Fig. 5b and Supplementary Fig. 8a). Such increases in CYP11B2 expression are rarely seen with pharmacological interventions but are comparable to differences between APAs and adjacent adrenal, for example, 78-fold for our index case. Silencing of GJA1 was less effective (Supplementary Fig. 8b–d). However, RNA sequencing (RNA-seq) data showed that, unlike in primary human adrenal tissues, H295R cells express twofold to threefold more GJC1 than GJA1 (Supplementary Table 5b). Indeed, silencing of both GJs increased CYP11B2 expression and aldosterone secretion (Fig. 5c and Supplementary Fig. 8e,f), mirroring the effects of the CADM1 variants.
To discover whether GJs would also regulate aldosterone production in ZG cells from primary human adrenal cultures, we repeated the Gap27 experiments in cells collected from the adrenal cortex adjacent to four APAs (Adr 1–4) and one cortisol-producing adenoma (Adr 5). In Ang II-stimulated primary cells adjacent to APAs, Gap27 increased CYP11B2 expression by ~12-fold and aldosterone secretion by ~4-fold, albeit with large variability between different adrenals (Fig. 5d). Less of an effect was seen on unstimulated cells (Supplementary Fig. 8g). No increase in Ang II-stimulated CYP11B2 or aldosterone production was seen in cells adjacent to the cortisol-producing adenoma (Adr 5; Supplementary Fig. 8h).
The effect of Gap27 on spontaneous and Ang II-triggered calcium oscillations was interrogated in H295R cells, using Fluo-4AM (Supplementary Note and Supplementary Fig. 9).
RNA-seq of mutant CADM1 cells reveals clock genes enrichment
Some of the common somatic mutations, for example, KCNJ5 and ATP1A1, combine loss of their physiological activity with a gain of function5,8,9,56. To explore further pathways by which CADM1 might influence aldosterone production, and whether these are physiological actions of native CADM1 or purely pathological, we performed RNA-seq of H295R cells transduced with vector alone, WT CADM1 and mutant CADM1 (both isoforms and both variants), and H295R cells transduced with a CADM1-specific or nontargeting shRNA. Additionally, RNA-seq was also performed on the index APA with p.Val380Asp variant and two other ZG-like APAs with somatic mutations of ATP2B3 or CACNA1D.
In the main experiment, CYP11B2 was the most upregulated gene (Fig. 6a,b and Supplementary Table 6a), averaging 14-fold across isoforms and variants, followed by a neuroendocrine gene not usually associated with adrenal cortex, secretogranin-2 (SCG2). Several other genes, upregulated twofold to tenfold, have strong adrenal associations: DPP4, MC2R and TSPAN12 are selectively expressed in APMs compared to ZG49; MC2R and MRAP are required for ACTH stimulation of cortisol; the rap guanine nucleotide exchange factor RAPGEF4 is exclusive to adrenal cortex and brain; SCG2 is unique to adrenal medulla, brain/pituitary; and the nonmuscle myosin MYOM1 distinguishes ZG- from ZF-like APAs8. In every case, as for CYP11B2 itself, the p.Val380Asp variant and longer (453 amino acids) isoform were more effective than p.Gly379Asp and 442-amino acid isoform.
The shRNA experiment confirmed the reduction in CYP11B2 seen previously on qPCR (Supplementary Fig. 10, Supplementary Table 6b and Supplementary Note).
Gene-annotation enrichment analysis and functional annotation clustering, using the Database for Annotation, Visualization and Integrated Discovery (DAVID), revealed biological rhythms as the most significant process, together with cell junction and synapse (Supplementary Table 7). A plot of expression change for each of the 14 biological rhythms genes showed that RORE and E-box genes formed two clusters with, respectively, up- and downregulated transcription (Fig. 6c). In most instances, small changes in cells transduced by WT CADM1 were in the opposite direction to mutant. Six of the 14 genes have significant diurnal patterns in mouse adrenal, with the peak for RORE genes out of phase with E-box genes (Supplementary Fig. 11). The steroidogenic gene STAR was increased by 25% (P = 1.0 × 10−8)57. One of the RORE-target genes, NPAS2, can replace CLOCK itself in dimers with BMAL1 (ref. 58), and is also upregulated in the index APA compared to other APAs with different genotypes (Supplementary Table 8). DAVID identified two significant Kyoto Encyclopaedia of Genes and Genomes (KEGG) pathways, ‘aldosterone synthesis and secretion’ and ‘axon guidance’, with 5.8-fold and 4.5-fold enrichment, respectively (Supplementary Table 9).
The most striking finding among genes upregulated in both sets of RNA-seq (variant versus WT transduced H295R cells, and the comparison of APAs) is the 19-fold upregulation of AQP2 (Supplementary Table 8). On IHC of the index APA, AQP2 appears in dense inclusion bodies (Extended Data Fig. 8). These are thought to be spironolactone bodies, assumed to be a form of aggresome originating in endoplasm reticulum (ER). Similar bodies are seen when AQP2 accumulates in ER as a consequence of the mutations that cause diabetes insipidus by preventing glycosylation and transport to the plasma membrane59. In two APAs from the replication cohort, there was patchy cytoplasmic staining for AQP2 (Extended Data Fig. 8). Supporting evidence that the rise in AQP2 may be relevant to aldosterone regulation came from its measurement in the RNA samples from Gap27-treated human adrenocortical cells and H295R cells transduced with CADM1 variants. We found that, in Ang II-stimulated primary adrenal cells treated with Gap27 and H295R cells transduced with mutant CADM1 (which increased CYP11B2 expression the most), AQP2 expression was also substantially increased (Extended Data Fig. 9).
Discussion
The discovery of pathogenic KCNJ5 variants in 30–40% of APAs, followed by several others, explained the onset of autonomous aldosterone production in most of these tumors, and highlighted smaller APAs as a distinct, easily overlooked, sub-tier in which size is inversely proportional to the density of aldosterone synthase8,11,12. These discoveries confirmed that aldosterone secretion is exquisitely sensitive to changes in membrane potential, but may have illuminated pathology more than physiology. Conversely, the six patients with p.Gly379Arg or p.Val380Arg CADM1 variants present an exceptional cause of PA. Following the discovery that primate and rodent adrenals have different origins, even rare human mutations are clues to important adrenal biology that could not be anticipated from rodent experiments—in this case, that GJs suppress aldosterone production in most of human ZG25,60.
CADM1, a member of the immunoglobulin superfamily, brings cells of the same or different type into contact and is best known as a CNS synaptogenic protein. Its importance was previously established in another endocrine tissue, pancreatic islets, where CADM1 enables β-cells to synapse with each other and with endothelial cells21. The neuronal features of ZG have been less remarked, but many of the molecules upregulated in APMs and ZG-like APAs are enriched in CNS, particularly cerebellum14,49,61. Herein, on transduction of CADM1 variants into adrenocortical cells, the gene with tenfold increase in expression, second only to CYP11B2 itself, was secretogranin-2 (SCG2, associated with neuroendocrine granules). In these experiments, the only KEGG pathways with significant enrichment were aldosterone synthesis and axon guidance, and the most differentially expressed biological processes were synapses, cell junctions and biological rhythms.
Of these three processes, our functional experiments concentrated on the specific triangle of CADM1 variant, inhibition of GJIC and CYP11B2 stimulation. A seemingly unique feature of human ZG is its sharp demarcation between foci of dense CYP11B2 expression, so-called APMs and the majority of cells where CYP11B2 is paradoxically switched off. Could GJIC be the cause? The role of GJIC in mutant CADM1 effects on aldosterone production was suggested by two observations. One was our previously reported inhibition by GJIC of glucagon secretion from islet α cells, and release of this inhibition by CADM1 knockdown18. The other observation was the change in protein orientation in another instance of spontaneous mutations creating a charged residue within the membrane domain of a single-pass membrane protein62. On the basis of fluorescence and Fourier transform infrared spectroscopy, G380R and A391E variants of FGFR3 straightened the TM helix tilt angle relative to the membrane. Structural modeling indicated a similar change, from acute to perpendicular orientation, for each of the CADM1 variants. We inferred that adjacent cells might be pushed beyond the reach of proteins that can only connect over a short distance. Like the grappling irons of historical naval warfare, GJs between two cells require each cell’s connexons to be in close proximity, estimated at <30 nm50,63.
GJs in ZF facilitate steroid hormone secretion, opposite to our observations in ZG. This again resembles pancreatic islet cells, in which slightly inconsistent literature suggests an opposite role for GJIC between α and β cells18,64,65. In our experiments on isolated cells, competitive blockade of the most abundant adrenocortical GJ protein increased CYP11B2 expression and aldosterone secretion by at least as much as CADM1 mutation. This is consistent with a tonic role for GJIC in the suppression of CYP11B2 expression in human ZG, outside the APMs, but further experiments will be required on fresh slices, retaining the physiological architecture (Supplementary Note).
Of the processes modified by these CADM1 variants, biological rhythms were not only the most significant but showed reciprocal change in clock genes whose endogenous changes in expression peak, respectively, at day or night. Several somatic mutations are associated with specific clinical phenotypes14,17. Our two initial patients had striking variability of plasma aldosterone at presentation. They are clearly too few to establish an association, but the interesting question is whether the phenotype explains the apparent rarity. A recent report that 24-h urine measurements find a much higher prevalence of PA than single-time measurements in blood suggested that patients missed by the latter have exaggerated or reversed diurnal rhythms66.
The individual cell clocks in tissue are coordinated by both extrinsic signals and cell–cell communication, including GJA1 (refs. 67,68). Whether CADM1’s regulation of clock genes, GJIC and synapses points to a role in coordination needs further investigation, together with the contribution of one further molecule, AQP2. This was the most upregulated gene in the RNA-seq of the index APA, and almost the only gene upregulated both in this APA and the variant-transduced H295R cells. AQP2 was densely present in the spironolactone-like inclusion bodies of the index APA (Supplementary Note).
In summary, we report a somatic mutation hotspot within the membrane dimerization domain of CADM1. The mutations, three each of p.Gly379Arg and p.Val380Arg, caused a many-fold increase in aldosterone production, and a form of hypertension that was cured by unilateral adrenalectomy. The mutations inhibited GJ communication between aldosterone-producing cells, and pharmacological inhibition of GJs replicated the effect of CADM1 variant on aldosterone production. GJs may underlie the suppression of aldosterone production in most human adrenal ZG.
Methods
Genetic analysis of patient cohort
All patients were confirmed to have a diagnosis of PA on the basis of a high aldosterone to renin ratio, ± hypokalemia, followed by confirmatory testing, when appropriate. Subtyping was performed by cross-sectional imaging (CT/MRI) and either adrenal vein sampling or 11C-metomidate PET-CT, as per local institutional and Endocrine Society guidelines1,69. All patients gave written informed consent for the study according to local ethics committee guidelines.
The index case was recruited from Addenbrooke’s Hospital, University of Cambridge (Cambridgeshire Research Ethics Committee), as part of 40 APAs to be sequentially whole exome sequenced. The second case was recruited from the University Hospital Munich—one of 81 APAs whole exome sequenced in the APA working group for the European Network for the Study of Adrenal Tumors, ENS@T (local Ethics Review Board, University Hospital Munich). Cases 3–5 were from Paris, recruited between 1999 and 2016 within the COMETE (COrtico- et Medullo-surrénale, les Tumeurs Endocrines) network (CPP Ile de France II Ethics Committee) identified by targeted sequencing. The final case was recruited from the Perelman School of Medicine at the University of Pennsylvania (with ethical approval from the Institutional review board, University of Pennsylvania), identified by next-generation sequencing.
In addition to the above, targeted Sanger sequencing was performed on a further 53 APAs from four centers as follows: Addenbrooke’s Hospital, University of Cambridge; St Bartholomew’s Hospital, Queen Mary University of London; Tohoku University Hospital, Sendai; and Graduate School of Biomedical and Health Sciences, Hiroshima University, Hiroshima.
Nucleic acid extraction
Genomic DNA (gDNA) was extracted from APA and adjacent adrenal tissue using QIAamp DNA Mini kit (Qiagen; UK cohort) or QIAamp DNA midi kit (Qiagen; French cohort). If the adjacent adrenal tissue next to an APA was not available for use as control, gDNA was extracted from blood using the salt extraction method. Total RNA was extracted using the Trizol method (Life Technologies) and either Invitrogen PureLink RNA mini kit or RNeasy mini kit (Qiagen). DNase I (Invitrogen) treatment was performed for all samples. If RNA later-preserved tissue was not available, total RNA was extracted from FFPE tissue blocks, cut from ten 4-μm FFPE sections using the RNeasy FFPE kit (Qiagen). RNA from H295R or primary adrenal cells was extracted using the PureLink RNA mini kit (without Trizol).
WES of Cambridge and German cohorts
WES of 40 pairs of APAs and adjacent adrenal from the Cambridge cohort and the 81 APAs from the German cohort are as previously published9,17.
Sanger sequencing of CADM1
Sanger sequencing was performed to confirm the somatic mutations of CADM1 identified by WES and to seek out further CADM1 variants in a replication cohort that was separate from those whole exome sequenced. PCR was performed with the primers listed in Supplementary Table 10, using AmpliTaq Gold Fast PCR Master Mix (Thermo Fisher Scientific), as per the manufacturer’s instructions; 100 ng of DNA in a final volume of 25 µl containing 400 nM of each primer, 200 µM deoxynucleotide triphosphate and 1.25 U Taq DNA Polymerase (Sigma-Aldrich). Sequencing was performed using BigDye Terminator v3.1 Cycle Sequencing Kit (Applied Biosystems; for French and German cohort); or commercially using Eurofin Sanger sequencing services (for UK cohort). GATC Viewer v.1.00 or UniPro UGENE v.1.28.1 were used for sequencing alignment.
Targeted next-generation sequencing (US cohort)
DNA was extracted from CYP11B2-positive tumor and adjacent normal adrenal cortex from formalin-fixed paraffin-embedded (FFPE) tissue sections using the AllPrep DNA/RNA FFPE Kit (Qiagen). Next-generation sequencing (NGS) libraries were constructed from FFPE-extracted DNA using a custom Ion AmpliSeq panel (Thermo Fisher Scientific) that targets the full-coding region of CADM1—as well as other known aldosterone-driver genes (ATP1A1, ATP2B3, CACNA1D, CACNA1H, CLCN2, CTNNB1, KCNJ5 and GNAS)—and sequenced using the Ion Torrent NGS System (Thermo Fisher Scientific)70,71.
Immunohistochemistry
IHC of control adrenals was performed using the EnVision FLEX+, Mouse, High pH kit (Dako, K8012). Fourteen adrenals with a unilateral APA undergoing follow-up treatment for PA at the University Hospital Hradec Kralove (n = 11) and the National University of Malaysia (UKM) Medical Center (n = 3) were used. As a non-APA adrenal control, one adrenal (control adrenal 1) from a 48-year-old Malay male with a large epigastric mass undergoing follow-up treatment for a pancreatic neuroendocrine tumor was also used. Usage of adrenals for investigations was approved by the local research ethics committee (the University Hospital Hradec Kralove Ethics Committee and UKM research ethics committee). Case detection and PA subtype identification were in accordance with local guidelines72,73,74. Incubation with primary antibodies (listed in Supplementary Table 11) was performed at room temperature for 30 min. Slides were also counterstained with Hematoxylin 2 (Thermo Fisher Scientific). The slides were mounted using DPX mounting medium (Merck Milipore) and images were captured using 3DHISTECH Pannaromic MIDI scanner (Software version 1.18).
For IHC scoring, a minimum of three ×20 images in selected areas of the scans that showed recognizable zonation of the adrenal cortex were captured using CaseViewer (Software version 2.4). All scoring of IHC scans were performed by two histopathologists independently after standardization using images captured from eight adrenals with 0 representing no staining, +1 representing weak staining, +2 representing intermediate staining and +3 representing intense staining (representative images of scores are shown in Supplementary Fig. 6e). An adrenal cortex region is considered APM, ZG, Z, or ZF based on IHC staining scores of CYP11B2, CYP17A1 and KCNJ5 as shown in Supplementary Table 12.
IHC for mutant CADM1 adrenals was performed as control adrenals (for 184T) or as per described below (for French cohort). In brief, IHC against CADM1 and AQP2 used citrate solution (0.935%, Vector Laboratories; 30 min at 98 °C) for antigen unmasking while IHC against CYP11B2 and CYP11B1 used Trilogy solution (5%, Sigma-Aldrich; 30 min at 98 °C). Endogenous peroxidases were inhibited by incubation in 3% hydrogen peroxide (Sigma-Aldrich) in water for 10 min. Nonspecific staining was blocked with 10% normal goat serum and 1× PBS (CADM1) or 1× TBS (AQP2) for 30 min; or Tris 0.1 M pH 7.4, 10% normal goat serum, 10% BSA and 0.1% SDS for 90 min (CYP11B2); or Tris 0.1 M pH 7.4, 10% horse serum and 0.5% SDS for 60 min (CYP11B1). The slides were incubated with primary antibody (listed in Supplementary Table 11) for 1 h at room temperature (CADM1 and AQP2) or overnight at 4 °C (CYP11B2 and CYP11B1). Sections were washed, incubated 30 min with affinity-purified goat anti-rabbit antibody (1/400, Vector Laboratories), and then washed and incubated with an avidin-biotin-peroxidase complex (Vectastain ABC Elite; Vector Laboratories) for 30 min. Slides were developed using diaminobenzidine (Vector Laboratories) and counterstained with hematoxylin (Sigma-Aldrich). Images were acquired using a Vectra automated imaging system software v.3.0.5 (PerkinElmer).
Immunofluorescence staining
For immunofluorescence staining, antigen retrieval was done by water bath incubation with pH 6.0 citrate buffer (Sigma-Aldrich) at 95 oC for 35 min. Samples were quenched by incubation with 0.1% Sudan black B, diluted in 70% ethanol for 25 min. Primary antibodies were incubated at 4 oC overnight whereas Alexa Fluor (AF) conjugated secondary antibodies diluted in blocking serum were incubated at room temperature for 1 h (antibodies listed in Supplementary Table 13). Wheat germ agglutinin (WGA) staining was performed with 5 μl ml−1 AF 647 conjugate (Invitrogen, W32466) before incubation with protein block serum-free (Dako). All sections were incubated with 300 nM DAPI stain, mounted with Vectashield Antifade mounting medium and cured for 24 h. Visualization of fluorophores was by TissueFAXS SL Q + upright epifluorescence microscope and viewed with TissueFAXS slide viewer 7.0 software. FIJI ImageJ software v1.8.0_72 was used to prepare the images for presentation.
Cell culture and drug treatments
Functional studies were performed using NCI-H295R cells (human adrenocortical cell line) or primary human adrenal cells. Both H295R and primary adrenal cells were grown in culture medium consisting of DMEM/Nutrient F12-Ham supplemented with 10% FBS, 100 U penicillin, 0.1 mg ml−1 of streptomycin, 0.4 mM l-glutamine and 1% insulin-transferrin-sodium selenite. Primary human adrenal cells were collected from adrenalectomy in culture medium and dispersed within 1–2 h of retrieval. ‘Normal’ adrenal tissue next to an APA was digested in 3.33 mg ml−1 collagenase type XI-S from histolyticum (Sigma-Aldrich, C9697) for 2 h, washed twice with PBS, and resuspended in culture medium. After 5–7 d, the primary adrenal cells were used for drug treatments, seeded between 1.5 and 1.75 × 105 cells per well and serum-starved in unsupplemented medium for 6 h before treatment. Cells were treated with Ang II at a concentration of 10 nM and Peptide Gap27 at 10–250 μM, for 24 h.
NIH-3T3 fibroblast cells used in Western blot experiments (due to their negligible endogenous expression of CADM1) were grown in DMEM culture medium supplemented with 10% FBS. HEK293T cells used to produce lentiviruses for transduction of CADM1 were cultured in high glucose DMEM supplemented with 10% FBS, 100 U penicillin, 0.1 mg ml−1 of streptomycin and 0.4 mM l-glutamine. All cells were maintained at 37 oC in 5% CO2.
Generation of pLOC plasmids
cDNA from H295R cells was used as a template to amplify the CADM1 gene, using Q5 DNA polymerase. Topo-FLAG- and MYC-tag sequences were incorporated up- and downstream of CADM1, respectively, using a TF-CADM1-F 5′ primer and M-CADM1-R 3′ primers (listed in Supplementary Table 14). The amplified PCR product was cloned into a pENTR vector using directional TOPO cloning technology (pENTR/D-TOPO Cloning Kit, Invitrogen). The Q5 site-directed mutagenesis kit (New England Biolabs) was used to insert the extra 33-bp sequence of the SP1 (453-amino acid isoforms), using Ins-Ex9A-F and Ins-Ex9A-R primers. The G379D and V380D variants were introduced via site-directed mutagenesis, using the primers G379D-F, G379D-R and V380D-F, V380D-R, respectively. The pENTR constructs were used for transfer of cloned cDNAs into pLOC vectors (kindly gifted by Celso Gomez-Sanchez, University of Mississippi) in an attL/attR recombination reaction using LR Clonase II enzyme mix (Invitrogen).
Generation of shRNA
The primers 5′-tccaattgtagaggataagtcatctgtTTTTTGGAAAAGCTTATCGATAC-3′ and 3′-tccaattgtagaggataagtcatctgccGGGGATCTGTGGTCTCAT-5′ were used to clone shRNA targeting CADM1 into pLVTH vectors using Q5 site-directed mutagenesis kit (NEB). The pLVTH was kindly gifted from Didier Trono (Addgene plasmid, 12262). The stem-loop sense (5′-GTCTACTGAATAGGAGATGTT-3′) and anti-sense (5′-AACATCTCCTATTCAGTAGAC-3′) sequences consisted of 21 bp each. For scrambled (nontargeting control) shRNA, the primers 5′-tccaacgaggttattacgtaaggtattTTTTTGGAAAAGCTTATCGATAC-3′ and 3′-tccaacgaggttattacgtaaggtatccGGGGATCTGTGGTCTCAT-5′ were used for cloning. The sense and anti-sense shRNA sequences used were 5′-ATACCTTACGTAATAACCTCG-3′ and 5′-CGAGGTTATTACGTAAGGTAT-3′, respectively.
Generation of pCX4bsr plasmids
The full-length cDNA for human CADM1 was obtained from human lung mRNA (BioChain) by reverse transcription and polymerase chain reaction with a primer set of 5′-agtctgaggcaggtgcccgacat-3′ and 5′-cagttggacacctcattggaac-3′. The double-stranded cDNA was subcloned into the Bluescript vector via the EcoRV site by TA cloning, and the formed vector (pBs-453-CADM1) was determined by sequencing to have no mutations. The EcoRI-XhoI fragment containing the cDNA insert was subsequently subcloned into the pCX4bsr vector via the EcoRI and NotI site after the XhoI and NotI sites were blunt-ended with the Klenow large fragment. An XhoI site was generated in the cDNA insert of pBs-453-CADM1 via site-directed mutagenesis using the oligonucleotides 5′-tctcgagca-3′. This allowed the generation of the 442-amino acid isoform of CADM1 using XhoI and Accl. PCR was performed using these two pBluescript vectors as DNA templates, with the primers shown in Supplementary Table 15, which also allowed the introduction of the two mutations, as appropriate, via site-directed mutagenesis. The PCR products were subcloned into pTA2 vectors (Toyobo) by TA cloning, and sequenced to confirm the successful generation of WT, G379D or V380D mutant CADM1 in both 442- and 453-amino acid isoforms. Finally, the DNA inserts were cut out from the vectors by EcoRI digestion, and subcloned into pCX4bsr vector via the EcoRI site.
Gene delivery using transfection
Overexpression of pCX4bsr and pLOC plasmids was achieved using Lipofectamine 3000 (Invitrogen). Cells were plated at 70% confluency and transfected after 24 h, using 1 μg of plasmid DNA and Opti-MEM (Gibco, Thermo Fisher Scientific). Cotransfection of H295R cells with pLOC and GJA1 vectors, or GJA1 and GJC1 targeting siRNA, was carried out by electroporation using Invitrogen’s Neon Transfection System. One microgram of DNA or 20 nM of siRNA was used for the 10 μl system and electroporated at the following conditions: 1,100 V, 40 ms, one single pulse.
Gene delivery using lentivirus
Lentivirus particles were generated using HEK293T cells transfected with pMD2, psPAX (both kindly gifted by Didier Trono; Addgene plasmid, 12259 and 12260), and pLOC vectors using polyethylenimine. Virus particles were concentrated using Amicon-15 filter units (Merck). Titration of the lentivirus vectors was achieved via flow cytometric (FACS) method (BD FACSDiva Software v6.1.3, BD Biosciences, and Flowing Software v.2.5.1) utilizing the GFP on the pLOC vectors75. Transduction was performed with 8 μg ml−1 of Polybrene using a multiplicity of infection (MOI) of 3–5 TU per cell.
Aldosterone concentration measurements
Aldosterone concentrations were measured using a Homogeneous Time Resolved Fluorescence assay by Cisbio. The fluorescent signals were read at 665 nm and 625 nm using a FLUOstar Omega plate reader software v5.7 (BMG Labtech). Due to the potential interaction of FBS in the medium with the aldosterone assay, all treatments were performed using serum-free medium.
Quantification of protein expression using western blotting
Cells transfected with pCX4bsr plasmids were lysed and immuno-blotted using a custom-made rabbit polyclonal anti-CADM1 antibody76 (1:2,000), generated against the C-terminal peptide sequence EGGQNNSEEKKEYFI77 or an anti-β-actin antibody (1:2,000; Medical and Biological Laboratories).
For experiments involving silencing of CADM1 using shRNA and silencing of GJA1 and GJC1 using siRNA, cells were lysed and immune-blotted using the following primary antibodies; anti-CADM1 C-terminal (Sigma-Aldrich, S4945; 1:5,000), anti-CADM1 N-terminal 3E1 (Medical & Biological Laboratories, CM004-3), anti-β-actin (Medical & Biological Laboratories, PM053; 1:2,000), anti-GAPDH (Sigma-Aldrich, G8795; 1:40,000), anti-GJA1 (Sigma-Aldrich, C6219; 1:8,000) and anti-GJC1 (Invitrogen, PA5-79311; 1:2,500). Secondary antibodies used include anti-mouse (Sigma-Aldrich, A3682; 1:40,000), anti-chicken (Medical & Biological Laboratories, PM010-7; 1:5,000) and anti-rabbit (Sigma-Aldrich, A0545; 1:40,000) antibodies.
Quantification of mRNA expression using RT–PCR
One microgram of RNA was reverse transcribed to cDNA using either Applied Biosystem’s High Capacity RNA-to-cDNA kit or AMV Reverse Transcriptase System (Promega). qPCR was used to quantify the level of mRNA expression of the genes of interest. This was performed using a C1000 Touch Thermal Cycler machine, CFX Manage TM Software v3.1 (Bio-Rad) or ABI 7900 Real-time PCR system, 7900 SDS v2.4.1 (Thermo Fisher Scientific) and the TaqMan Fast Advanced Gene Expression Master Mix (Applied Biosystems, 4369514). The genes of interest were identified using commercially available probes from Thermo Fisher Scientific, with Assay ID listed in Supplementary Table 16. Results were analyzed using the 2−ΔΔCT method, using the housekeeping gene 18S rRNA or β-actin for normalization, unless otherwise specified.
Dye transfer assays
H295R cells of 2.5 × 105 were plated and transfected with pLOC vectors described above. Forty-eight hours after transfection, the cells were transferred into the on-stage CO2 incubator of a confocal laser microscope (C2, Nikon), which was also equipped with a micromanipulation system. A single, GFP+ cell was injected with 200 μg ml−1 of AF 647-conjugated WGA (Invitrogen) and 20 μg ml−1 of calcein red AM (CellTrace, Invitrogen). The micromanipulation system was set as follows: microcapillary angle: +60o, FemtoJet 5247 injection pressure: 200 hpa, injection time 2 s, postinjection pressure: 100 hpa. Fluorescent and differential interference contrast images were captured immediately after injection to confirm dual-color labeling of the GFP+ cells, followed by repeat images taken 1 h after injection. WGA, which is impermeable through GJ, was used to identify the original cell injected, while the GJ permeable calcein red was used to visualize intercellular GJ communication. The number of calcein red positive cells within a 50-μm radius of the WGA labeled, original cell injected was counted and expressed as a percentage of the total number of cells within the 50-μm radius. The same technique was used to measure dye transfer in H295R cells treated with soluble CADM1 immunoglobulin-ectodomain, using Dil (Invitrogen) as the GJ impermeable dye and BCECF (Dojindo) as the GJ permeable dye. In these experiments, H295R cells were treated with either 10 μg ml−1 of soluble CADM1 (secreted form of CADM1 fused to the Fc portion of immunoglobulin G (IgG)41) or 10 µg ml−1 of Fc control (secreted form of CADM1 that lacks 3 immunoglobulin-like loops, fused to the Fc portion of IgG) for 24 h before injection of dyes.
Protein modeling
Three-dimensional structures of the TM domain (residues, A375–L395) of WT, G379D and V380D mutant CADM1 was modeled using QUARK (March 2018)78. These structures were embedded in the lipid bilayer, which was composed of 128 dipalmitoylphosphatidylcholine molecules and then soaked in explicit water molecules79,80. The SPC water model was used to solvate the protein and counter ions. These molecules were subjected to structural optimization by using GROMACS (2019 version)81 with the GROMOS 53a6 force field. Energy minimization and molecular dynamics analysis were carried out in accordance with the established methods82. The 3D structures of the stalk region of CADM1 for both isoforms (residues, Y329–V376 in SP4 and residues, Y329–V385 in SP1) were also analyzed by using QUARK. The most stable structure of each isoform was joined to the 3D structure of Ig-like domains (residues, K50–T345), which was obtained from ModBase83 (model ID, 7f7df202e8d6aa361f9ca3847afe4608) by using the PyMOL Moledular Graphics System software (version 2.1, Schrödinger). The secondary structure of each isoform was analyzed by DSSP84. The distances between the most separated atoms in the stalk regions were measured by PyMOL. The tilt angle of the TM helix of WT, G379D and V380D with respect to the bilayer was analyzed by hydrophobic mismatch85. The length of the shortest TM helix (V380D) was used as thickness of the lipid bilayer. The tilt angle of the TM helix, θ, was given by the following formula:
where h is the length of the TM helix of CADM1.
After the confirmation of validity in these CADM1 structures based on the trajectories and 3D quality under the Ramachandran plot, to determine the model structure of cis-homodimer for the 442- and 453-amino acid isoforms of CADM1, docking simulation was performed by using ZDOCK v.3.0.2 software86. Tetramer models were simulated and analyzed using the same procedure as for dimer modeling. Two thousand docking runs were performed under the definition of Ig-like V-type domain (residues Q45–T139) as a docking site. The docking poses of trans-tetramer for isoform 1 and trans-tetramer for isoform 4 were classified into six groups, respectively. The complex with the highest ZDOCK score was selected for each binding model. Intercell membrane distance deduced by trans-homophilic binding of WT, G379D and V380D were calculated by \(d=l\times \sin \theta\), where l is the length of extracellular domain of CADM1 trans-tetramer and θ is the angle of the ectodomain to the cell membrane defined by equation 1. Statistical analysis was performed using R software. Differences in intercell membrane distances were evaluated using one-way ANOVA with Tukey’s post hoc test. Data represent the mean ± s.d., with P < 0.05 regarded as statistically significant.
The protein structure of the TM domain of CADM1 was also separately modeled using Phyre2 v.2 (ref. 87). TMDOCK88 was used to predict the insertion and homodimerization of the TM region of the WT and Phyre predicted variant (G379D and V380D) structures in the cell membrane bilayer.
Visualizing GJ formation in H295R cells
Electroporation was used to cotransfect one pool of H295R cells with the aforementioned pLOC vectors containing WT or mutant CADM1 and the mApple-tagged GJA1 vectors. A second pool of H295R cells was transfected with Venus-tagged GJA1 vectors. After 48 h, the cells were trypsinized, mixed and reseeded into eight-well glass-bottom chamber slides coated with poly-l-lysine (Ibidi). Forty-eight hours post-trypsinization, GJ formation in the cells was visualized using a Spinning Disk Confocal microscope and the NIS-Elements v4.5 software (Nikon).
Laser capture microscopy (LCM)
Ten micrometer thick slices of fresh frozen ‘normal’ adrenal adjacent to an APA were mounted onto Zeiss-membrane slides under RNAse-free conditions for LCM. Serial sections were fixed and stained with 1% Cresyl violet (Sigma-Aldrich), allowing visualization of the different zones of the adrenal. ZG and ZF cells were collected by LCM technique using a Zeiss PALM microbeam laser dissection system (Carl Zeiss). Samples were frozen on dry ice immediately post-collection and stored at −80 oC. ZG and ZF samples dissected from eight to ten slices from the same adrenal were pooled for each RNA extraction, using Applied Biosystems’ PicoPure RNA Isolation Kit.
Calcium oscillation experiments
H295R cells were plated in 24-well glass bottom plates (Ibidi) at 1.5 × 105 cells per well. Cells were treated with 10 nM of Ang II or 250 μM of peptide Gap27 for 24 h, before incubation with 2.5 μM of Fluo-4AM for 45 min. Subsequently, cells were washed with PBS and re-instilled with the relevant drugs diluted in serum-free, phenol-red-free medium. Imaging was performed using LSM800 microscope (Zeiss) and analyzed using Fiji ImageJ v.1.52p Java 1.8.0_172. Fluo-4AM calcium measurements for individual cells were recorded and expressed as ‘mean cell fluorescence’ and graphed over time to visualize calcium flux/oscillations within each cell. To allow comparison between drug treatments, all microscope parameters (for example, laser power, collection bands, pixel size, detector gain and offset) were kept constant throughout the experiment. The baseline fluorescence (F0) for each cell was calculated by averaging the lowest fluorescence intensity of ten frames of a 50-frame ‘window’, repeated at two further distinct time points where the calcium flux was identified to be at baseline. In traces where no oscillations/’events’ were identified, the 50-frame windows were set to start at three equally spaced intervals89,90,91.
RNA-seq of H295R cells expressing CADM1 variants
Extracted RNA from H295R cells transduced with empty pLOC vector (EV), WT CADM1 and mutant CADM1 (both isoforms and both variants), treated with or without Ang II, was sequenced by the Barts and the London Genome Center, Blizard Institute in London. Quality control was performed using Agilent RNA 6000 nano reagent kit and run on an Agilent 2100 bioanalyzer (Agilent). Only samples with a RIN number >0.8 were sequenced. Library preparation using the mRNA library prep method was performed using NEBNext Ultra II RNA Library Prep Kit from Illumina. Sequencing was performed on Illumina’s NextSeq 500 system, using the high-output 150-cycle kit v2.5 and bcl2fastq Conversion Software. Partek Flow (Partek) was used for RNAseq analysis. Sequences were aligned hg38 with STAR −2.6.1d and annotated genes to Ensembl Transcripts release 93 with Partek’s own annotation tool. Partek’s GSA tool was used to generate lists of differentially expressed genes. Genes with a fold change >1.5 or <0.7 and ANOVA P < 0.001 between WT and variant transduced cells were selected for analysis using DAVID Bioinformatics Resources v.6.8 (refs. 92,93).
Statistics and reproducibility
All parametric data are presented as mean ± s.e.m., or median ± interquartile range, for nonparametric data. Statistical analysis was performed using GraphPad Prism v8.4.3 or R software v.3.5.0. All statistical tests were two-sided where applicable. For parametric data, comparisons between two groups were made using Student’s t-test, or by one-way analysis of variance (ANOVA) for groups of three or more. For nonparametric data, the Mann–Whitney test was performed when comparing two groups, or the Kruskal–Wallis test for groups of three or more. Post hoc analysis between three or more groups was performed using Dunn’s or Sidak’s multiple comparisons test. Normality testing was performed using Shapiro–Wilk Test. P < 0.05 were considered statistically significant.
Immunostaining in Extended Data Fig. 1–8 and Supplementary Figs. 5a–e, 6a–c, e and 7a–c were only performed once with no primary antibody controls and only after positive tissue controls showed the expected staining. Time-lapse imaging of GJ formation in cocultured H295R cells shown in Fig. 4c was performed in two independent experiments.
Reporting summary
Further information on research design is available in the Nature Portfolio Reporting Summary linked to this article.
Data availability
The RNA-seq data used to generate Fig. 6, Supplementary Fig. 10, and Supplementary Tables 5b and 6–9 are provided in Supplementary Data 1–3. The WES raw data are publicly available from the Sequence Read Archive (https://www.ncbi.nlm.nih.gov/sra/docs/) under accession numbers PRJNA732946 and PRJNA729738. Source data are provided with this paper.
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Acknowledgements
We thank C. E. Gomez-Sanchez (University of Mississippi Medical Center, Jackson, MS, USA) and D. Trono (Queen Mary University of London, London, UK) for their kind gifts of custom-made CYP11B2 antibody, and pLVTH, pMD2 and psPAX vectors, respectively. We are grateful to J. Hogenesch, L. A. Luong, J. Zhou, G. Argentesi and S. M. O’Toole for their thoughtful discussions. This work was supported by the following UK funding bodies: National Institute for Health Research (NIHR, Efficacy and Mechanisms Evaluation project 14/145/09 to M.J.B., W.M.D., M.G.), the British Heart Foundation (PhD studentship FS/14/75/31134 to M.J.B. supporting S.G.), Barts Charity (Project MGU0360 to M.J.B. and W.M.D.), NIHR Barts Biomedical Research Center (BRC-1215-20022 supporting M.J.B.), NIHR Integrated Academic Training Clinical Lectureship (to W.M.D. and M.J.B., supporting X.W.), NIHR Cambridge Biomedical Research Center (BRC-1215-20014 supporting M.G.), UKRI (MR/S007776/1 to F. Buss) and Wellcome Trust (104955/Z/14/Z to A.D.). E.A.B.A. was funded by the UK-MY Joint Partnership on Noncommunicable Diseases 2019 program (NEWTON-MRC/2020/002) and the Royal Society-Newton Advanced Research Fellowship (NA170257/FF-2018-033). C.P.C. was funded by the NIHR as part of the portfolio of translational research of the NIHR Biomedical Research Center at Barts and The London School of Medicine and Dentistry. E.G. was supported by a Medical Research Council (UK) Fellowship, MR/S006869/1. This research used Queen Mary’s Apocrita HPC facility (https://doi.org/10.5281/zenodo.438045), supported by QMUL Research-IT. Immunofluorescence images were acquired in the Blizard Advanced Light Microscopy Suite. The work in Japan was supported by the Japan Society for the Promotion of Science KAKENHI grants (18K07414 to Y. Takaoka, 17K08680 to M.H., 21K08557 to K.O., and 15K15113, 18K07049 to A.I.); the Ministry of Education, Culture, Sports, Science and Technology-Supported Program for the Strategic Research Foundation at Private Universities 2015-19 (to A.I.); grant from Takeda Science Foundation (to M.H.); and grants from the Ministry of Health, Labour, and Welfare, Japan (20FC1020 to F.S.). M. Murakami was supported by the Japan Heart Foundation/Bayer Yakuhin Research Grant Abroad and a postdoctoral fellowship of the Uehara Memorial Foundation. The work in Paris was supported through institutional funding from Inserm, by the Agence Nationale de la Recherche (ANR-18-CE93-0003-01) and the Fondation pour la Recherche Médicale (EQU201903007864 to M.-C.Z). Other funding bodies include the National Medical Research Council and Biomedical Research Council, Singapore (to R.S.F.); the National Science Foundation grant MC-2011577 (to S.A.M.); the large research infrastructure project BBMRI.cz LM2023033 (to A.R.); Else Kröner-Fresenius-Stiftung in support of the German Conn’s Registry‒Else Kröner Hyperaldosteronism Registry (2013_ A182, 2015_A171 and 2019_A104 to M.R.), the European Research Council under the European Union’s Horizon 2020 research and innovation program (grant agreement 694913; to M.R. and grant agreement 633983 to F. Beuschlein), the Deutsche Forschungsgemeinschaft (DFG) within the CRC/Transregio 205/1 ‘The Adrenal: Central Relay in Health and Disease’ to M.R. and F. Beuschlein, and by the Clinical Research Priority Program (CRPP HYRENE) and the University Research Priority Program (URPP ITINERARE) of the University of Zurich (to F. Beuschlein).
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X.W., E.A.B.A., E.G., S.G., M.H., F.L.F.-R., S.B., M.-C.Z., F. Beuschlein, A.I. and M.J.B. conceived and designed the experiments/analyses. S.A.M. provided critical interpretation. C.P.C., J.L.K., Z.T., C.A.M., E.W. and R.S.F. contributed to WES or RNA-seq production, validation and analysis. A.D. and Y. Takaoka generated the protein modeling data. R.S.S helped with calcium oscillation experiments. F. Buss provided the GJA1 constructs. J.S. undertook clinical assessments of the index case. Y. Tezuka, F.S., K.O., P.J.K., A.M.U. and W.E.R. undertook searches for additional CADM1 variants. W.M.D., M.G., M.R., D.L.C., H.W., M.-C.Z. and M.J.B. recruited patients in whom CADM1 variants were found. J.C., A.R. and M.S. collected and contributed adrenal samples for genotyping and/or IHC, which was performed by W.Z., A.M. and M. Murakami. The IHC scoring was performed by Y.P.W. and G.C.T. with imaging by E.A.B.A. M. Mustangin undertook quantification of GJA1 in adrenal IHC. Immunofluorescence staining was performed by E.G. The manuscript was prepared by X.W., E.A.B.A. and M.J.B. All authors read and approved the manuscript.
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Extended data
Extended Data Fig. 1 Characteristics of CADM1 V380D mutant APA.
a, Hematoxylin and eosin staining of CADM1 V380D mutant APA (P1). Low and high power views of hematoxylin and eosin staining in APA of P1 displaying compact cells and numerous spironolactone bodies (black arrows). b,c, Immunohistochemistry for CYP11B2 (b) and CADM1 (c) in CADM1 V380D mutant APA (P1). CADM1 is highly expressed in the APA (red box) and adjacent aldosterone-producing micronodules (APM, blue box), with membranous staining also seen in the medulla. The magnified area of the red box shows the border between adrenal medulla and APA, whereas the blue box shows CADM1 peri-capsular staining of the outer cortex. Scale bar as indicated on image.
Extended Data Fig. 2 Characteristics of CADM1 G379D mutant APAs.
a,b, Immunohistochemistry for CYP11B2 and CYP11B1 in CADM1 G379D mutant APAs. Staining of CYP11B2 (a) and CYP11B1 (b) was inversed (strong CYP11B2 staining in APA with faint CYP11B1). A similar pattern was seen with CADM1 V380D mutant APAs. c, Immunohistochemistry for CADM1 in CADM1 G379D mutant APAs (P2, P4, and P5). Cross-sectional scans and zoomed images of CADM1 staining of APA from patients P2, P4, and P5. Again as seen with CADM1 V380D mutant APAs (Extended Data Fig. 1c), the CADM1 protein appears membranous and is most highly expressed in the outer cortex and adenoma. Scale bar as indicated on image.
Extended Data Fig. 3 GJA1 expression in human adrenals.
a, GJA1 cDNA expression in laser capture microdissected (LCM) zona glomerulosa (ZG) samples. Left, selective cresyl violet staining of ZG for LCM RNA sample extraction. The capsule (C), zona fasciculata (ZF), and zona reticularis (ZR) do not retain the cresyl violet dye. Right, PCR of cDNA from LCM ZG and ZF RNA samples. HepG2 cells were used as a negative control as they do not express GJA1. ZF LCM samples had 5.45-fold higher expression of GJA1 cDNA than ZG LCM samples. Full-length gels are provided as Source Data Extended Data Fig. 3. b, Immunohistochemical GJA1 staining in the absence and presence of the antigen peptide. Adrenal sections from patient P1 were immunostained with GJA1 antibody (C6219, Sigma-Aldrich) in the absence or presence of the competing antigen peptide. Comparison of the serial sections show true staining of GJA1 protein in ZG/pericapsular adrenal cells, although less than ZF cells. Identification of adrenal zones were based on IHC for ZG and ZF markers shown in Supplementary Fig. 4c.
Extended Data Fig. 4 Different cellular expression of GJA1.
a, Zona fasciculata (ZF) staining of GJA1 in regions of CYP17A1 positive (+ve) cells. Membranous GJA1 staining (anti-GJA1, HPA035097, Sigma-Aldrich) in ZF, on IHC (left) and immunofluorescence (IFC, right). These cells far from the capsule of the adrenal cortex were positive for CYP17A1 (image of CYP17A1 shown in Extended Data Fig. 2e). Nuclei of cells were stained with either hematoxylin (IHC) or DAPI (IFC, blue). Puncta staining detected by IFC similar to that seen with IHC is highlighted by white arrows. b, Zona glomerulosa (ZG) staining of GJA1 in regions of CYP17A1 negative (-ve) cells. Punctate staining of GJA1 (anti-GJA1, HPA035097, Sigma-Aldrich) at sites of ZG cell contacts, on IHC (left) and IFC (right). These cells adjacent to the capsule (C) were negative for CYP17A1. Nuclei of cells were stained with either hematoxylin (IHC) or DAPI (IFC, blue). Puncta staining detected by IFC similar to that seen with IHC is highlighted by white arrows.
Extended Data Fig. 5 GJA1 expression in peri-capsular cells expressing VSNL1 (ZG marker) co-localizes with wheat germ agglutinin (WGA; cell membrane marker).
IFC staining of CYP17A1, VSNL1 (a ZG marker), and GJA1 was performed on serial sections from an adrenal harboring an APA. IFC staining color-coded as indicated in image. A no primary (1°) antibody control was performed to take into account autofluorescence that occurs in the region. GJA1 punctate expression, annular GJ (white arrow), and GJ plaque (yellow arrow) co-localizes with WGA in VSNL1 positive (+ve) cells. Left, scans of the serial sections. Right, zoomed image within boxed regions in scans. Bottom, image of the CYP17A1 positive cells shown in Extended Data Fig. 4.
Extended Data Fig. 6 Presence of annular GJA1 in APM regions (CYP11B2-expressing cells).
IFC staining of CYP11B2 and GJA1 was performed on serial sections of the same adrenal shown in Extended Data Fig. 5. IFC staining is color-coded as indicated in image. GJA1 expression in APM regions was lower compared to adjacent adrenal cortex. Annular GJs (red arrows) were present in APM. Top, scan of the serial adrenal section; Bottom, zoomed images of ZF region and APM regions highlighted in scan.
Extended Data Fig. 7 GJA1 and TJP1 expression is decreased in CYP11B2-expressing ZG cells.
a, APM regions (CYP11B2-expressing cells) have less GJA1 expression on cell membrane. IFC staining of WGA (white), CYP11B2 (green), and GJA1 (red) in an adrenal harboring an APA. Reduced membranous expression of GJA1 and a few annular GJs (red arrows) are seen in CYP11B2-positive cells (red box insert). Linear gap junction plaques (orange box insert) with budding annular GJs (white arrows) can be seen where WGA and GJA1 co-localize (orange staining). b, TJP1 expression is also decreased in APM compared to adjacent ZG. IHC for CYP11B2, GJA1, and TJP1 in adrenal sections from patient P1. IHC for GJA1 was performed using the same antibody as in Extended Data Fig. 2b. GJA1 and TJP1, another cell junction protein, had decreased expression in APM (demarcated by black dashed lines) compared to adjacent ZG (demarcated by the red dashed lines). Membranous GJA1 staining in ZF and punctate GJA1 staining in ZG are highlighted by black and red arrows, respectively.
Extended Data Fig. 8 Heterogeneous subcellular expression of AQP2 in CADM1-mutant APAs.
IHC for APQ2 was performed on a positive control tissue section (from a human kidney) and on adrenal tissue sections containing APA of P1 (top right), APA of P4 (bottom left), and APA of P5 (bottom right). Selective membranous staining (black arrows) was seen in the collecting ducts of the human kidney, whereas using the same parameters, APA of P1 had solitary cytoplasmic bodies staining with AQP2 (red arrows), while APAs of P4 and P5 had apparent cytoplasmic staining (blue arrows).
Extended Data Fig. 9 AQP2 expression in adrenal cells treated with Gap27 or transduced with mutant CADM1.
a, AQP2 mRNA expression in primary human adrenal cells treated with Gap27 in the presence or absence of angiotensin II (Ang II). AQP2 mRNA expression of cells from Fig. 5d and Supplementary Fig. 7g is shown. mRNA expression for primary adrenal cells was normalized by β-actin. Fold change was expressed relative to Ang II-stimulated cells (left) or untreated cells (right) for each adrenal (n = 10). Data represent mean, error bars show s.e.m. Statistical analysis was performed using two-sided Student’s t-test. AQP2 expression was significantly increased in stimulated cells treated with Gap27 (***P = 0.0002) but not in unstimulated cells (P = 0.730). b, AQP2 mRNA expression in cells transduced with wild-type (WT) or mutant CADM1 (V380D or G379D). Transduction of mutant CADM1 (both mutants in 442aa and 453aa isoforms) increased AQP2 mRNA expression compared to wild-type in Angiotensin II (Ang II) stimulated H295R cells (n = 6). This trend was also seen in unstimulated cells. All values expressed as average fold-change of both isoforms (3 independent wells each) relative to untransduced cells. Data represent mean, error bars show s.e.m. Statistical significance between groups were measured using the two-sided Kruskal-Wallis H test; Unstimulated, χ2(2) = 7.362, P = 0.0177 and Ang II-stimulated, χ2(2) = 8.592, P = 0.0076, respectively. Post-hoc analysis performed using Dunn’s multiple comparison test, compared to WT. AQP2 mRNA expression was significantly increased in unstimulated V380D (*P = 0.0138) and stimulated G379D (**P = 0.0335) and V380D (***P = 0.0155) cells. n = biological independent replicates from 3 independent experiments. The underlying statistics are provided as Source Data Extended Data Fig. 9.
Supplementary information
Supplementary Information
Supplementary Figs. 1–11, Supplementary Tables 1–16, supporting data for Supplementary Figs. 2a–c and 8c,f (uncropped scans of blots) and Supplementary Note
Supplementary Data 1
Number of RNA-seq reads matching to each gene for each sample that were transfected with either empty vector control, or WT or variant (G379D or V380D) long isoform (453) or short isoform (442) of CADM1 or untransfected. Both Ang II-stimulated or vehicle control (untreated) were interrogated.
Supplementary Data 2
Number of RNA-seq reads matching to each gene for each sample that were transfected with either nontargeting or ShCADM1.
Supplementary Data 3
Number of RNA-seq reads matching to each gene for each sample consisting of three APAs (tumor) and their normal adjacent adrenal (normal) including APA 184T from the index case (P1).
Supplementary Data 4
Statistical supporting data for Supplementary Figs. 1–11.
Supplementary Video
Time-lapse of H295R cells transfected with GJA1 vector constructs labeled with either the mApple or Venus fluorophores cocultured together to show internalization of a GJ plaque from two adjacent cells, followed by the formation of an annular GJ (AGJ) in one of the two cells comprising of GJ protein from both.
Source data
Source Data Fig. 2
Full-length blots.
Source Data Fig. 2
Statistical source data for Fig. 2c–e.
Source Data Fig. 3
Full-length blots (long exposure and very long exposure (to show protein ladder).
Source Data Fig. 4
Statistical source data for Fig. 4b,d.
Source Data Fig. 5
Statistical source data for Fig. 5b–d.
Source Data Fig. 6
Uncropped heatmap with gene names.
Source Data Extended Data Fig. 3
Full-length gels of Extended Data Fig. 3a (along with GAPDH control).
Source Data Extended Data Fig. 9
Statistical source data for Fig. 9a,b
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Wu, X., Azizan, E.A.B., Goodchild, E. et al. Somatic mutations of CADM1 in aldosterone-producing adenomas and gap junction-dependent regulation of aldosterone production. Nat Genet 55, 1009–1021 (2023). https://doi.org/10.1038/s41588-023-01403-0
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DOI: https://doi.org/10.1038/s41588-023-01403-0
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