Immunomodulation therapy offers new molecular strategies to treat UTI

Innovative solutions are needed for the treatment of bacterial infections, and a range of antibacterial molecules have been explored as alternatives to antibiotics. A different approach is to investigate the immune system of the host for new ways of making the antibacterial defence more efficient. However, the immune system has a dual role as protector and cause of disease: in addition to being protective, increasing evidence shows that innate immune responses can become excessive and cause acute symptoms and tissue pathology during infection. This role of innate immunity in disease suggests that the immune system should be targeted therapeutically, to inhibit over-reactivity. The ultimate goal is to develop therapies that selectively attenuate destructive immune response cascades, while augmenting the protective antimicrobial defence but such treatment options have remained underexplored, owing to the molecular proximity of the protective and destructive effects of the immune response. The concept of innate immunomodulation therapy has been developed successfully in urinary tract infections, based on detailed studies of innate immune activation and disease pathogenesis. Effective, disease-specific, immunomodulatory strategies have been developed by targeting specific immune response regulators including key transcription factors. In acute pyelonephritis, targeting interferon regulatory factor 7 using small interfering RNA or treatment with antimicrobial peptide cathelicidin was protective and, in acute cystitis, targeting overactive effector molecules such as IL-1β, MMP7, COX2, cAMP and the pain-sensing receptor NK1R has been successful in vivo. Furthermore, other UTI treatment strategies, such as inhibiting bacterial adhesion and vaccination, have also shown promise.

Innate immunity provides a rapid and selective first line of defence 1-4 , preventing pathogens from gaining access to host tissues while sustaining symbiosis with the commensal flora. This impressive level of precision is maintained by specific pathogen recognition mechanisms coupled with the immediate activation of the innate immune system [4][5][6][7][8] (Fig. 1). Health is rapidly restored when the innate immune response is efficient and transient, but an imbalanced response can create exaggerated inflammatory states and cause severe acute disease, mortality and chronic sequelae 9 . By targeting and correcting these weaknesses therapeutically, a functional innate immune response can be restored and the bacteria removed.
The adaptive immune response adds antigen specificity and longevity to the host defence (Fig. 1). Antigens on invading pathogens are recognized and memory is created to prevent recurrent infections 24 . An adaptive immune response is detected in patients with APN, but the protective role of this immune response remains unclear [25][26][27] . In mice, gene deletions affecting adaptive immunity have not been found to drive disease development but to weaken the defence [28][29][30][31] . X-linked immunodeficient and RAG1-deficient mice, with attenuated B and T lymphocyte function, were not more susceptible to E. coli-induced UTIs than controls and had low bacterial counts after 24 h (reFs 15,32 ). Additionally, αβ T cell-deficient and ɣδ T cell-deficient mice did not show increased susceptibility to kidney infections 28 . However, some studies have suggested that severe combined immunodeficiency mice have increased bacterial burden compared with wild-type mice during UTI 28,33 . Additionally, T helper 17 (T H 17) cell responses have been proposed to affect bacterial clearance, based on reduced neutrophil and macrophage infiltration in IL-17A-deficient mice 17 . Sentinel natural killer (NK) cells have been proposed to influence resistance to uropathogenic Escherichia coli (UPEC) infection through mechanisms involving the release of TNF; however, the underlying protective mechanisms of this cell population remain unknown and additional depletion studies will be essential to fully understand the role of NK cells in UTI 34 . In addition, resident macrophages in the bladder suppress T H 1-mediated immunity and macrophage depletion helps the host to clear the infection, but T cell depletion had no effect on bacterial clearance, confirming that myeloid cells rather than lymphocytes are essential for UTI pathogenesis 35 .
The WHO has declared antimicrobial resistance 1 of the top 10 global public health threats facing humanity; thus, novel antimicrobial therapeutic strategies are urgently needed 36 . UTIs are among the most prevalent bacterial infectious diseases globally 37,38 , most often caused by UPEC originating from the gut flora or perineal flora 39,40 . E. coli infections account for half of the estimated global burden of antibiotic resistance 36,41,42 , with about 90% of E. coli strains being resistant to at least one antibiotic 43 . In Europe, UPEC isolates are resistant to third-generation cephalosporins and fluoroquinolones (11.8 % and 22.3% of UPEC strains, respectively) 44 and fluoroquinolone-resistant UPEC were 31.3% of the isolates in hospitalized patients with UTI 45,46 .
In this Review, we discuss innate immune hyperactivation as a disease determinant in UTI and identify targets for innate immunomodulatory therapy. We envisage that this new approach might benefit large patient groups in the future. The use of innate immuno modulation therapy would be similar to antibiotics, aiming to reduce acute inflammation and infection but, in contrast to antibiotics, innate immunomodulation therapy might offer a solution for treating infections caused by antibiotic-resistant strains. Furthermore, efforts to develop UTI vaccines and other prophylactic measures are discussed, as well as investigations into broad anti-inflammatory therapies such as NSAIDs.
Disease determinants in acute pyelonephritis APN is a severe, sometimes life-threatening infection 37,47,48 , initiated by UPEC strains that attack the renal pelvic mucosa and elicit a local innate immune response that is amplified and becomes systemic [49][50][51][52] . Local symptoms at the site of infection are triggered by excessive kidney inflammation and the systemic spread of inflammatory mediators generates fever and general malaise in the infected patient [53][54][55] . APN is accompanied by urosepsis in ~30% of adults, and urosepsis remains a major cause of mortality, especially in the elderly [56][57][58][59] . The mortality rate in APN was estimated to be 10-20% before the introduction of antibiotics, and a frequency of 7.4% was recorded

Key points
• excessive innate immune responses to infection cause symptoms and pathology in acute pyelonephritis and acute cystitis. • Innate immunomodulation therapy is, therefore, a realistic option for treating these conditions. • Targeting excessive innate immune responses at the level of transcription has been successful in animal models. • Innate immunomodulation therapy reduces excessive inflammation and tissue pathology and accelerates bacterial clearance from infected kidneys and bladders in mice. • Innate immunomodulation therapy also accelerates the clearance of antibiotic-resistant bacterial strains.

Fig. 1 | Innate and adaptive immune responses to UTI.
The mucosal immune system controls susceptibility to infection by regulating the defence against pathogenic microbes. Pathogen recognition mechanisms mobilize a rapid innate immune response and activate the antibacterial defence, resulting in efficient clearance of infection. A balanced response is essential, as loss of homeostasis might cause disease as mechanisms intended for protection to underperform or overreact. Innate immunotherapy is aimed at correcting such weaknesses and restoring the efficiency of the immune defence in the host. a | Schematic overview of the innate immune response to mucosal infection. Uropathogenic E. coli triggers Toll-like receptor 4 (TLR4) signalling in responding cells in the mucosal barrier and the release of pro-inflammatory mediators activates a rapid local innate immune response cascade, which might become systemic. Cytokines with paracrine activity stimulate cells in the mucosal environment, chemokines recruit neutrophils from the circulation and infected nerve cells participate in a neuroinflammatory loop involved in pain sensing. Bacteria are cleared by the direct effects of antibacterial molecules, such as defensins, as well as neutrophils, which phagocytose the bacteria and exit with their cargo across the mucosal barrier into the urine. A number of additional defence mechanisms may be activated as well. The response is mostly transient and infection is cleared but host defects that reduce the efficiency of bacterial clearance or increase the inflammatory response are associated with increased disease severity. b | Adaptive immunity is activated by infection when antigens from infecting bacteria reach antigen-presenting cells and activate local or distant lymphocyte populations. Plasma cells producing specific antibodies have been identified in the kidneys and bladder, especially in mice with a deficient neutrophil response. Infected patients secrete secretory IgA (sIgA) antibodies into the urine, which inhibit bacterial adherence 49 . Circulating antibodies are detected in patients, with acute pyelonephritis and plasma cells detected in infected kidneys of susceptible mice 79 . Lymphoid aggregates might form in chronically infected individuals and specific T cell populations regulate the efficiency of the host defence by affecting the crosstalk between innate and adaptive immunity 7,8 . in 2005, after the introduction of antibiotics 60 . In addition, APN is an important cause of renal growth retardation and permanent kidney damage in childhood, leading to chronic sequelae such as hypertonia, renal insufficiency or renal failure as well as premature delivery [61][62][63][64] .

Molecular control of the innate immune response in APN
Mechanisms of APN pathogenesis and innate immune activation have been extensively studied and reviewed [4][5][6]29 . Briefly, pathogen-specific recognition mechanisms  10,11 . The severe pathology in Irf3 −/− mice is contrasted against protection in Irf7 −/− mice 11 , and Irf7 overactivation has been identified as an essential disease mechanism. b | Innate immunomodulation therapy was achieved by targeting IRF7 in infected Irf3 −/− mice 11 . Liposomal Irf7 siRNA was used as an Irf7-silencing strategy and treatment substantially reduced kidney pathology and accelerated bacterial clearance compared with untreated mice. Irf7 siRNA treatment had similar therapeutic efficacy to cefotaxime treatment at an intermediate dose. c | Severe acute cystitis is driven by IL-1β overactivation involving the MMP7 protease. Bladders become enlarged, hyperaemic and nerve cell activation triggers a pain response. The disease severity is illustrated by images from infected mice, showing enlarged, oedematous bladders with evidence of hyperaemia in Asc −/− and Nlrp3 −/− mice compared with C57Bl/6 mice 12 . d | This severe cystitis phenotype can be reversed by treatment with an IL-1 receptor antagonist (IL-1RA) or an MMP7 inhibitor, which inhibits the excessive IL-1 response, reduces inflammation and accelerates bacterial clearance 12 . Furthermore, blocking the pain response by targeting NK1R has been shown to reduce pain behaviour and inflammation in Nlrp3 −/− mice 13 . Liposomal IRF7 siRNA treatment and IL-1RA treatment were shown to have similar efficacy to antibiotics in reducing the disease severity, illustrating the potential of this interesting new immunomodulatory approach for treating UTIs. Part c adapted from reF. 12  activate a rapid innate immune response in infected tissues, leading to inflammation and the mobilization of an antibacterial defence 65 . Specific bacterial adherence strategies are essential, involving surface fimbriae or non-fimbrial adhesins and host cell receptors 16,54,66,67 . P fimbriae are expressed by 90-100% of UPEC strains in patients with uncomplicated APN 68 , with a strong association with disease severity, and have been proposed to facilitate bacterial invasion, leading to urosepsis 49,65,69,70 .
Different arms of the TLR4 signalling cascade can be engaged, depending on the fimbrial adhesins and virulence factors that the pathogens express 16,54,66,67,[97][98][99] . P fimbriated UPEC strains mainly activate the adaptor proteins TIR-domain-containing adapter-inducing interferon-β (TRIF) and TRIF-related adaptor molecule (TRAM) 16,85,93,94 and the phosphorylation of mitogen activated protein (MAP) kinases, p38 and cyclic AMP-responsive element-binding protein (CREB) defines signalling cascades downstream of TLR4, which converge on specific transcription factors (including IRF3, IRF7, AP-1 and NF-κB) 10,93 . The resulting pro-inflammatory cascades include cytokines in the kidneys, such as type I interferons, IL-6 and TNF, and IL-1 in the bladder, as well as neuropeptides (substance P (SP) and galanin) and their receptors. Chemokines (IL-8 (also known as CXCL8), CCL3 (also known as MIP1α), CCL5 (also known as RANTES) and CCL2 (also known as MCP1)) 12 TRAM  TRAM   TLR4   TRAM  TRAM   TLR4   TRAM  TRAM  TRIF  TRIF  TRIF  TRIF  TRIF  TRIF Fig. 3 | Molecular basis of Irf7 siRNA-based therapy for acute pyelonephritis. a | Uropathogenic, P fimbriated Escherichia coli activates a TLR4-dependent signalling cascade in the renal pelvic epithelium involving the TRIF-TRAM adaptor proteins, ultimately leading to transcription factor activation and an active defence. The balance between transcription factors IRF3 and IRF7 is essential to control the quality of the defence and the outcome of infection 10,11 . The IRF3 response is protective, limiting inflammation and promoting bacterial clearance. b | By contrast, an overactive IRF7 response is destructive and leads to acute pyelonephritis, with potentially severe consequences for renal health. c | Irf7-specific siRNA treatment was shown to inhibit the excessive IRF7 response and to effectively reduce kidney pathology in Irf3 −/− mice 11 . siRNA treatment also accelerates bacterial clearance, in a manner similar to antibiotics.
The essential role of TLR4 signalling in UTI was first observed in Tlr4 -/mice 82 Pro-CASP1

Fig. 4 | Molecular basis of excessive IL-1 signalling in acute cystitis and immunomodulatory treatment approaches.
Uropathogens trigger the TIRAP-MyD88 arm of TLR4 signalling and activate NF-κB, which transcribes pro-inflammatory cytokines, most prominently IL-1β, a key mediator of bladder pathology. a | In wild-type mice, IL-1β is activated by NLRP3inflammasome processing, leading to a transient, self-healing, inflammatory response peaking at 3 days. The ASC and NLRP3 proteins are essential inflammasome constituents, which facilitate the processing of pro-caspase 1 and cleavage of pro-IL-1β. b | Surprisingly, Asc −/− and Nlrp3 −/− mice develop an excessive IL-1β response, increased pyuria, bacteriuria and severe bladder pathology. The overactive IL-1β response is explained by a non-canonical mechanism of IL-1β processing by matrix metalloproteinase 7 (MMP7) 12 . c | Innate immunomodulation therapy approaches to inhibiting IL-1β signalling. IL-1 receptor antagonist (IL-1RA)-based therapy (anakinra) considerably reduced acute cystitis severity in Asc −/− mice and accelerated bacterial clearance 12 . d | Blocking MMP7 using batimastat (an MMP inhibitor) inhibited IL-1β processing, reducing disease severity with a decrease in gross pathology and bacterial counts compared with untreated mice 12 .
www.nature.com/nrurol response 32,106 . To identify the TLR4-dependent mechanisms of disease, single genes in the TLR4 pathways have been systematically deleted and the resulting phenotypes have been characterized in UPEC-infected mice 10 . Specific gene deletions have been shown to create an APN or ACY disease phenotype, providing essential insights into the mechanisms of disease pathogenesis. Irf3 −/− mice lack the protective IRF3-dependent arm of innate immunity and develop severe APN, characterized by hyperinflammation, urosepsis and massive renal abscess formation 10,11 . IFNβ is activated downstream of IRF3, and Ifnb1 −/− mice showed a similar severe APN disease phenotype to Irf3 −/− mice 10 . A strong APN phenotype is also observed in Cxcr2 −/− mice, deficient in the chemokine receptor CXCR1, which regulates neutrophil activation and neutrophil exit from infected kidneys into the urine 14,79,114 . The Cxcr2 −/− mice develop severe APN with urosepsis and acute mortality, accompanied by renal abscesses 14,115 . Pathology is caused by massive neutrophil retention in the kidneys, as recruited neutrophils fail to exit into the urine and to scavenge and kill the bacteria 14,115,116 . The Cxcr2 −/− mice also develop renal damage resembling renal scarring in children with APN 14,79,116 . Neutrophil recruitment is rapid, regulated by the urothelial chemokine response to infection 100,117 and release of high levels of TNF from epithelial cells and resident mast cells, which support the neutrophil response 54,89,118 . Cells in the subepithelial compartment, including dendritic cells, are affected through increased IL-1β and IL-1R expression 119 and infiltrating neutrophils have high COX2 expression and release of prostaglandin E 2 (PGE 2 ) affects inflammation 120 . The chemokine receptors are essential determinants of the disease response, by controlling neutrophil activation and migration 121 .
C5aR1 has been identified as a determinant of APN disease progression in mice using decreased bacterial counts, lymphocyte infiltration and kidney pathology in the kidneys in C5ar1 −/− mice compared with wild-type controls 122 . Furthermore, bacterial burden and neutrophil and macrophage infiltration was decreased in P2x7 −/− mice, suggesting a role of the purinoreceptor P2X 7 in APN and associated renal fibrosis 123 . Finally, increased bacterial burden in the kidneys of Car2 −/− mice suggested that carbonic anhydrase 2 in intercalated cells in the kidneys might promote renal bacterial clearance 124 .

Human relevance of the genetic screens
The human relevance of these findings has been supported by clinical studies 10,78,125 . IRF3 promoter sequence variants were detected in two APN-prone patient populations 10 . The homozygous A/A-C/C genotype (nucleotide positions −925 and −776) was prevalent the APN-prone patients (79%), whereas the co-segregating heterozygous single-nucleotide polymorphisms (SNPs) were more common in those with asymptomatic bacteriuria (ABU; 69%) 10 . The APN haplotype was shown to decrease IRF3 expression in reporter assays, suggesting that IRF3 needs to be fully functional to avoid APN 10 . CXCR1 mRNA levels are low in children with APN and CXCR1 expression is reduced 78 . APN-prone patients carry heterozygous CXCR1 polymorphisms affecting receptor expression and the presence of CXCR1 variants has been confirmed in several APN-prone patient groups 126,127 . CXCL8 SNPs were detected in infected patients with renal involvement confirmed by positive dimercapto succinic acid (DMSA) scans 125,127-129 . In addition, PTX3 is polymorphic in APN-prone children and in adults who suffer from recurrent cystitis 18 . IL10 polymorphisms were identified in APN-prone patients 80 as well as SNPs in CCL5, encoding the eosinophil and T cell chemoattractant RANTES 130 , supporting human disease relevance.
The information obtained from these studies is essential, as it provides a framework for distinguishing protective from destructive molecular determinants of the innate immune response and for targeting the cause of disease therapeutically.

IRF7 siRNA innate immunotherapy in APN
The transcription factor IRF7 takes over the innate immune response and drives disease pathology in Irf3 −/− mice (Fig. 3), in which IRF7-dependent gene networks are strongly upregulated, including Tlr4, Stat3 and Il6 as well as downstream genes involved in the acute phase response 11 . Upregulation of IRF7 expression and IRF7-dependent gene networks is also observed in patients with febrile UTI, supporting the human relevance 11,99 . Direct binding of IRF-7 to promoter DNA fragments (OAS1, CCL5 and INFB1) was demonstrated, supporting the role of IRF7 as a transcriptional regulator, especially in hosts with reduced IRF3 expression 99 . Further evidence supporting the role of IRF7 was obtained in infected Irf7 −/− mice, which were protected from infection and showed no evidence of kidney pathology 11 . IRF7 was further identified as an important transcriptional mediator during group b streptococcus-induced UTI 131 .
The protected phenotype in Irf7 −/− mice and overactivation of Irf7 in disease-prone Irf3 −/− mice identified IRF7 as a potential therapeutic target. Using an short interfering RNA (siRNA)-based strategy of Irf7 inhibition 11 , siRNA treatment of Irf3 −/− mice was shown to inhibit the excessive innate immune response in Irf3 −/− mice and to improve bacterial clearance, resulting in resolution of infection by day 7 (Fig. 3). siRNA therapy compared favourably with antibiotic treatment and Irf7 siRNA treatment considerably reduced the disease score 11 . Importantly, Irf7 silencing immunomodulation therapy accelerated bacterial clearance to the same extent as cefotaxim 11 . Furthermore, recombinant IFNγ treatment was shown to increase survival, reduce bacterial burden and reduce kidney pathology in a rabbit model of APN, compared with untreated rabbits 132 .
The IL-6 response to UTI was first described in the 1980s 53,133 ; IL-8, IL-1 and TNF were also detected. The IL-6-STAT3 pathway is activated in the kidneys of infected Irf3 −/− mice, shown by transcriptomic analysis and tissue staining 11 . The IL-6-STAT3 response is IRF7-dependent, and this pathway is inhibited in mice treated with liposomal Irf7 siRNA. The role of IL-6 in an APN mouse model has been investigated 19 . In Il6-knockout mice with experimental UTI, STAT3 phosphorylation was significantly reduced but total STAT3 expression was unchanged. Furthermore, levels of STAT3 transcriptional targets were reduced. Inhibition of IL-6, using an IL-6 neutralizing antibody in Il6-intact mice, resulted in reduced IL-6 levels and decreased bladder and kidney STAT3 phosphorylation in response to UPEC infection, increased bacterial burden, as well as abscess formation, supporting a role for this cytokine in the host defence 19 .
The IL-6-STAT3 pathway is also activated in patients infected with P fimbriated bacteria 99 , and IRF7 has been identified as a key transcription factor driving the response in these patients. IL-6 and other cytokines were subsequently measured in patient urine in a number of studies, in which the levels of these cytokines correlated positively with bacterial virulence and disease severity, fever and CRP 75,100,134 . A strong effect of P fimbriation, a feature that defines this virulence factor as a host response inducer 66,67 , was also observed in these studies. The early studies led to further detailed analysis of TLR4 and the TLR4-dependent signalling pathway that activates IL-6-STAT3 10,53,81 .
These results highlight how individual transcription factors regulate beneficial or destructive effects of innate immunity and identify IRF7 as a target for immunoregulation therapy in APN.
Clinical trials support the feasibility of siRNA-based therapies for indications including familial amyloidosis, haemophilia and hepatitis C [135][136][137][138] . The use of siRNA-based therapies in humans is still developing, and the challenges of off-target effects, pharmacokinetics and immune activation need to be addressed for this approach to be a clinical reality 139,140 . However, positive effects of siRNA therapy have been observed in human experimental trials 141,142 , and the successful development of RNA-based vaccines suggests that such technologies should be clinically feasible. The Irf7 siRNA treatment approach is intended to be acute, with similar treatment protocols to those used for antibiotics, which is essential in order to avoid long-term suppression of the immune system and effects on the susceptibility to other infections, including those of viral origin.

Anti-inflammatory therapies in APN
APN is caused by exaggerated inflammation in infected kidneys. A number of general anti-inflammatory agents have been tested in animal models of APN, with limited benefits 120,143,144 . Early studies showed that glucocorticoids attenuate inflammation, but they also impaired bacterial clearance 145 . NSAIDs inhibited the inflammatory response but the infection was not cleared in treated mice 145 . These results indicate that broad inhibition of the inflammatory response does not equal protection against disease and support the conclusion that drugs with increased specificity are needed to achieve an anti-inflammatory and antibacterial effect.

Antimicrobial peptides
Antimicrobial peptides (AMPs) are effectors of the innate immune response and resemble antibiotics, in that they mainly target the bacteria rather than the immune system per se 146,147 . AMPs, including defensins, have been investigated as therapeutics owing to their direct antibacterial effects 18,[146][147][148] . AMPs (including β-defensins, ribonucleases and cathelicidin) are potent effectors of the renal defence against infection 147,[149][150][151][152][153] . RNase7 and cathelicidins act by disrupting the phospholipid membranes of various microorganisms and are constitutively synthesized by the kidney 147,151,152 . Lipocalin 2 (LCN2; also known as NGAL) is a specific antibacterial protein secreted both in the urine and systemically after Gram-negative infection, kidney injury or urosepsis. LCN2 binds the bacterial siderophore enterochelin, preventing iron transfer and sequestration by the bacteria 154 . The humoral pattern recognition molecule pentraxin 3 (PTX3) serves as an opsonin and promotes bacterial uptake by neutrophils 18 .
The cathelicidin AMP (CAMP) LL-37, which is primarily released by macrophages and neutrophils, targets UPEC strains in vitro 147 . Cramp −/− mice (CRAMP is an LL-37 homologue) showed reduced pathology compared with wild-type controls after infection with the E. coli cystitis strain UTI89 (reF. 155 ), and Cramp −/− mice infected with the pyelonephritis strain E. coli CFT073 were protected 147 , supporting a role in the antimicrobial defence, similar to antibiotics 147,155 . Although positive results have been observed in vitro and in knockout mice in vivo, further studies are required to address if purified AMPs can be administered as a therapeutic in disease models.
Immunomodulation in acute cystitis ACY is mainly caused by bacterial infections of the urinary bladder 37,68 . The patients experience pain, dysuria and frequency of urination, and the diagnosis is supported by the presence of bacteriuria and pyuria 37,156,157 . A subset of susceptible patients develop severe ACY with an excessive innate immune response, severe symptoms and pathology 158 . Recurrent infections are common, and chronic inflammation can lead to sequelae such as interstitial cystitis/bladder pain syndrome (IC/BPS) 159,160 .
Type 1 fimbriae act as virulence factors in the mouse urinary tract [161][162][163] , mediating bacterial adherence to the bladder mucosa [88][89][90][91] . The FimH adhesin binds several mannosylated host cell glycoconjugates and has been proposed to facilitate bacterial invasion of mucosal cells 92 . TLRs control the innate immune response to E. coli infection in the bladder, and Tlr4 −/− mice are protected from disease 16,32,106,111 . Type 1 fimbriated strains preferentially activate the MyD88 and TIRAP adaptors and NF-κB-dependent effector functions 88,[162][163][164][165] . A pro-inflammatory effect of type 1 fimbriae has been observed in a mouse model, but not in human studies using isogenic strains differing in fimbrial expression 99 . In contrast to P fimbriae, which triggered an IRF7-driven inflammatory response in the patients, direct effects of type 1 fimbriae on innate immunity were not detected in patients 99 . Type 1 fimbriae were shown to inhibit basic cellular functions such as RNA translation and effects on neurosensing and solute carriers suggested a potential link to the host reponse 99 .

IL-1 hyperactivation as a cause of acute cystitis
IL-1β is a potent pro-inflammatory cytokine that amplifies innate immune responses in several chronic infection models, including cystic fibrosis, tuberculosis www.nature.com/nrurol and inflammatory bowel disease 9,[166][167][168] . ACY has been identified as an IL-1β hyperactivation disorder triggered by E. coli infection of the bladder mucosa in a mouse model 12 (Fig. 4). Clinical ACY isolates activated pro-IL-1β expression in human 5637 bladder epithelial cells in vitro, and the processing and release of mature IL-1β were accelerated 12 . The IL-1 response to E. coli infection is controlled by TLR4 and transcription factors, including ERK, p38 and NF-κB 169,170 . In addition to IL-1β, a cascade of IL-1-dependent genes is activated, and effectors of the host response include IL-8 and PGE 2 as well as SP and NK1R 12,13 .
Genetic screens further identified a non-canonical mechanism of IL-1β hyperactivation that creates severe ACY 12,13 (Fig. 4). The inflammasome controls pro-IL-1β processing in many models; therefore, inactivating gene deletions affecting the inflammasome would be expected to be protective. Instead, a severe ACY disease phenotype was observed in infected mice carrying single-gene deletions of Nlrp3 or Asc 12 . The excessive, disease-associated IL-1β response in Asc −/− mice was further mapped to the protease MMP7 and the pain sensors NK1R and SP, which were overexpressed 12,13 . Direct molecular interaction studies attributed the excessive IL-1 response to pro-IL-1β processing by MMP7 (Fig. 4), and included a cascade of IL-1β-dependent, downstream genes 12 . Importantly, Il1b −/− mice were protected against infection and inflammation, further supporting the importance of IL-1β in this disease 12,94 . The human relevance of these findings was supported by elevated urine IL-1β levels in patients with ACY, compared with patients with ABU 12 .

IL-1 receptor antagonist treatment of acute cystitis
IL-1β and its receptor are potential therapeutic targets for immunomodulation therapy in ACY (Fig. 4). The recombinant human IL-1 receptor antagonist (IL-1RA) protein binds to IL-1R1 with similar affinity to IL-1α and IL-1β, inhibiting their binding and the dimerization of IL-1R1 and the IL-1 receptor accessory protein, as well as downstream signalling 9 . The IL-1RA anakinra was, therefore, investigated as an inhibitor of IL-1β hyperactivation in ACY (Fig. 2). Asc −/− mice, which are susceptible to ACY, were treated with daily injections of anakinra for 7 days and disease severity and bacterial clearance were quantified at sacrifice 12 . Anakinra treatment reduced tissue pathology by 75-80% compared with untreated mice and the inflammatory response to infection was markedly attenuated, as shown by reduced neutrophil numbers in urine and bladder tissue as well as reduced IL-1-dependent gene expression. Furthermore, bacterial clearance was accelerated, suggesting that correcting the immune imbalance empowers the innate immune response of the host. The efficacy of anakinra treatment was verified in C57Bl/6 wild-type mice with intact inflammasome function 13 , which exhibit a milder, more transient disease phenotype than Asc −/− mice.
Anti-inflammatory effects of IL-1RA have been demonstrated in several hyper-inflammatory diseases such as rheumatoid arthritis, gout, cryopyrin-associated periodic syndrome [171][172][173] and in bacterial and viral infection models including cystic fibrosis 175 and COVID-19 (reFs 174,176 ), supporting the feasibility of exploring the beneficial effects of IL-1RA as a therapeutic in patients with ACY 175,177,178 .
The efficiency of IL-1RA therapy was compared with that of antibiotic therapy in Asc −/− mice infected with fully virulent E. coli strains. IL-1RA therapy showed similar efficacy to cefotaxime and both treatments accelerated bacterial clearance 179 ; however, IL-1RA therapy inhibited the hyper-inflammatory response in infected bladders more effectively than cefotaxime, indicating an added benefit. In addition, IL-1RA therapy accelerated the clearance of extended-spectrum β-lactamase (ESBL)-producing E. coli strains against which cefotaxime was inefficient 179 .
The results of innate immunomodulation therapy in a mouse model of ACY provides a rationale for initiating clinical trials of IL-1RA therapy in ACY.

Therapeutic effects of MMP inhibition in acute cystitis
Mmp7 expression was strongly upregulated in mice that developed severe ACY, as shown by genome-wide transcriptomic analysis of whole-bladder mRNA 12 . MMP7 was also shown to cleave pro-IL-1β to its mature, active form (Fig. 4). Based on these findings, the broad MMP inhibitor batimastat (also known as BB-94) was tested for therapeutic efficacy using the same protocol as for IL-1RA treatment 12 (Fig. 2). The severity of ACY was markedly attenuated in the treated mice, as shown by reduced urine and tissue neutrophil levels and a substantial decrease in pathology scores (Figs 2,4). Furthermore, treatment accelerated bacterial clearance but to a lower extent than IL-1RA treatment 12 . These results indicate that batimastat or related compounds might be of interest to explore as a potential treatment alternative in ACY.

Pain attenuation in acute cystitis
Pain is a hallmark of ACY and symptom relief is a key result of ACY therapy. Pain is commonly regarded as secondary to inflammation and is defined as one of its hallmarks 180 . Pro-inflammatory cytokines promote pain by sensitizing nerves and activating transcription and release of pain molecules such as nerve growth factor (NGF), PGE 2 , MMP9 and the neuropeptide SP, which is an effector molecule of inflammatory pain 181,182 . SP is released by several cell types and engages neurokinin receptors, particularly NK1R 183 (Fig. 5). The interaction between SP and NK1R helps to propagate peripheral pain signals from local afferent nerves to the dorsal roots of the central nervous system 184 .
SP is spontaneously released within the bladder wall 185 and binds to NK1R, triggering the peripheral pain response 184 . LPS was proposed to cause the pain response during UPEC infection via a non-inflammatory TLR4-dependent mechanism, but the effector mechanisms of this response were not defined 186 . A direct effect of infection on the nervous system has been detected owing to elevated SP and NK1R levels in UPEC-infected nerve cells in vitro 13 . Increased levels of SP and NK1R were also detected in the bladder mucosa of UPEC-infected mice and accompanied by increased pain behaviour. The SP-NK1R response was shown to be hyperactivated in Asc −/− and Nlrp3 −/− mice through a neuroinflammatory loop controlled by IL-1β and NK1R 13 (Fig. 5). Urine SP levels were also found to be elevated in patients with ACY, suggesting the human relevance of this mechanism and a potential for use of SP as a biomarker of symptomatic lower UTIs and ACY 13 . Interestingly, Nlrp3 and Asc were shown to control the expression of NK1R and SP and the processing of IL-1β, linking inflammation and pain in mice susceptible to ACY. Owing to the strong connection between SP and NK1R expression and pain in experimental ACY, an NK1R antagonist (SR140333) was investigated for therapeutic efficacy in Nlrp3 −/− mice 13 (Fig. 5). NK1R antagonist treatment reduced NK1R staining in bladder tissue sections as well as Nk1r and Ppt-A mRNA levels in whole-bladder mRNA 13 . A marked decrease in tissue pathology (oedema, hyperaemia and mucosal integrity) was detected, and treatment inhibited IL-1 superfamily gene expression, inflammation, cytokine production and adaptive immunity 13 . These results suggest that pain from the urinary tract during ACY involves SP and NK1R signalling and that treatment with an NK1R antagonist can reduce symptoms and inflammation in UPEC-infected mice (Figs 2,5).

Human relevance of innate immunomodulation therapy in the urinary tract
The extent to which these successful treatment strategies in mice can be translated to human ACY needs to be investigated in controlled clinical studies; however, insights into the human relevance of innate immunomodulation therapy have been gained in patients with IC/BPS 187 . These patients experience severe and debilitating pain during bladder filling, resulting in extreme urgency and frequency 188,189 . IC/BPS has a prevalence of about 0.1% and affects all aspects of life, as even morphine and morphine analogues fail to provide adequate symptom relief [188][189][190] . Numerous therapeutic approaches to IC/BPS have been tested in preclinical studies including NK1R antagonists and various chemicals 185,191,192 , such as protamine sulphate, to induce urothelial cell shedding and facilitate bacterial clearance from the urinary tract 193 ; however, the results of these studies have not been sufficiently convincing for human use 194 . More specific therapies have been lacking owing to poor understanding of the disease mechanisms. The IL-1β-dependent and NK1R-dependent pain response in the mouse ACY model suggested that IL-1RA therapy might be an option for this patient group. Patients with severe IC/BPS (n = 17) were, therefore, offered off-label IL-1RA treatment 187 , and ~70% of the patients showed an initial treatment response, characterized by a reduction in pain and micturition frequency and an increased quality of life, quantified by O'Leary's symptom score (7.2 versus 17.4) 187 . Clinical improvement was accompanied by a reduction in urine SP levels and gene expression analysis revealed considerable effects on neuroinflammatory and inflammatory gene sets, including IL-1, IL-6 and IL-8 signalling pathways, which were inhibited 187 . After the initial treatment cycle, 13 of the patients chose to continue IL-1RA treatment and individual treatment protocols have proven efficient in the long term (>1 year) 187 .
These results provide clinical evidence that IL-1RA therapy might be useful and effective in patients with IC/BPS, but controlled clinical trials should be performed to validate these effects. In addition, studies of IL-1RA therapy might be of interest to treat IL-1β-induced symptoms and pathology in ACY, but clinical data are not yet available.

Additional approaches to inhibiting innate immunity in acute cystitis
A variety of anti-inflammatory regimens have been tested as therapeutics in ACY 47 . Numerous studies have shown that broad anti-inflammatory agents such as corticosteroids and NSAIDs reduce inflammation in UTI models 145,195,196 , but have adverse effects on bacterial clearance.
Controlled clinical studies have compared diclofenac or ibuprofen with antibiotics, but no significant benefits were detected for bacterial clearance or symptom relief 144,197,198 . In a study of 181 women with ACY, comparing a 3-day ibuprofen course with pivmecillinam, approximately half of the patients who received ibuprofen had persisting or worsening symptoms during the 4-week follow-up period compared with 10% of patients treated with the antibiotic 198 . In studies comparing ibuprofen with fosfomycin treatment, symptom burden was increased in 34% in the ibuprofen group 143,144 . In one study, NSAID treatment with diclofenac was associated with an increased risk of APN 197,198 .
Another mechanism by which ACY, specifically recurrent cystitis, is mediated in mice is through cyclooxygenase 2 (COX2), which catalyses the rate-limiting step in the conversion of omega-6 arachidonic acid to prostanoids and is involved in the development of acute inflammation. In mice sensitized to develop recurrent cystitis, Ptgs2, which encodes COX2, showed a 50-fold increased expression in bladder tissues from UPEC-infected mice, and immunofluorescent antibody staining of bladder sections showed robust expression of COX2 by urothelial cells in bladders exhibiting severe inflammation 120 .
Specific inhibition of COX2, using a selective COX2 inhibitor (SC-236), was shown to reduce bladder inflammation and bacterial load in a mouse model of ACY, consistent with the role of inflammation in the disease process 120 ; by contrast, a COX1 inhibitor did not significantly affect inflammation or bacterial counts 120 . Furthermore, SC-236-treated mice had lower bladder bacterial titres 24 h after infection than those treated with the COX1 inhibitor, suggesting that bacterial clearance was facilitated by the blockade of COX2.

Forskolin regulates exocytosis of E. coli in bladder epithelial cells.
In a mouse model in which mice were catheterized and intravesically instilled with the type 1 fimbriated UPEC strain CI5, bacterial invasion into bladder epithelial cells was found to be mediated through fusiform vesicles 199 . Further in vitro investigations showed that E. coli infection of 5637 bladder epithelial cells initiated bacterial incorporation into secretory lysosomes and release of the secretory lysosomes. Secretory lysosomes are stimulated through Fig. 5 | Inhibition of neuroinflammation in the bladder. a | Overview of the mucosal pain response to infection. Acute cystitis is accompanied by pain, owing in part to direct bacterial infection of the nerve cells and increased expression of the mucosal pain sensors substance P (SP) and NK1R in epithelial cells and nerve fibres. SP binds to NK1R, initiating a pain signal, which is propagated to the central nervous system. b | The pain response is further amplified by an IL-1β-driven inflammatory loop. c | Inhibition of pain and disease response by treatment with IL-1 receptor antagonist (anakinra) or the NK1R inhibitor SR140333 (reF. 13 ). d | Staining of tissue sections from the bladder of infected mice, showing increased expression of Substance P and NK1R in Asc −/− and Nlrp3 −/− mice compared with C57Bl/6 wild-type (WT) mice 13 . e | The SP and NK1R response was inhibited, using a selective NK1R antagonist, which also reduced bacterial counts and tissue pathology. Part d adapted from reF. 13 , CC BY 4.0 (https://creativecommons.org/ licenses/by/4.0/). Part e adapted from reF. 13 , CC BY 4.0 (https://creativecommons.org/ licenses/by/4.0/). intracellular Ca 2+ levels and cyclic AMP (cAMP) flux, and discharge their contents in response to fluctuations in these factors. E. coli infection was observed to induce Ca 2+ -sensitive and cAMP-sensitive exocytosis of secretory lysosomes from bladder epithelial cells. Further investigation showed E. coli inside the exocytosed lysosomes 199 .
Forskolin is a labdane diterpene that stimulates adenylate cyclase and increases intracellular levels of cAMP. Using forskolin in combination with gentamicin in BALB/c mice, a reduction in intracellular bacterial numbers was detected in bladder tissue, and urine IL-6 levels were lowered 199 .
These results suggest that broad anti-inflammatory agents lack specificity as they affect both the protective and the destructive arms of innate immunity.
Immunomodulation by molecules of bacterial origin Bacteria are an interesting source of molecules that regulate innate immunity in the host. In contrast to virulence factors, which can have detrimental effects, bacterial molecules have been shown to target the transcriptional machinery or TLR signalling and inhibit the innate immune response, resulting in a protective effect. These molecules have an interesting potential as candidates for innate immunomodulation therapy.

Bacterial NlpD inhibits Pol II-dependent gene expression
In early experiments, ABU strains were shown to inhibit host gene expression by targeting the RNA Pol II phosphorylation machinery 200,201 (Fig. 6). The RNA Pol II cycle controls RNA synthesis through numerous precisely regulated steps 202 . Productive RNA elongation requires phosphorylation of the RPB1 subunit, and this step was inhibited by most ABU strains 200 . The bacterial protein NlpD has been identified as an active inhibitor released by ABU and faecal E. coli isolates under normal growth conditions 201,203,204 . NlpD is internalized by host cells and inhibits gene expression broadly, including effects on several pro-inflammatory mediators.
NlpD was further shown to act as an innate immune inhibitor in UPEC-infected mice treated with the recombinant NlpD protein. Inflammation was suppressed and bacterial clearance accelerated following intraperitoneal NlpD administration 201,204 (Fig. 6). The results identify NlpD as an efficient immunomodulator with therapeutic efficacy in a mouse UTI model. Further studies are required to determine the suitability of NlpD for human trials.

Bacterial TIR domain homologues inhibit innate immunity
The evolution of mechanisms that specifically interfere with TLR-mediated immune responses in bacteria is not surprising given the central role of the TLRs in host defence 16,[82][83][84] . TIR domain homologues (TIR-containing proteins (TCPs)) have been detected in bacteria and viruses [205][206][207] , and ~20% of clinical urinary tract isolates belonging to the B2 clade express the TIR-containing protein TcpC 94,206,208 . TcpC attenuates signalling cascades   defined by the TIR domain of molecules such as MYD88,  TIRAP, TRIF, TRAM and IL-1R, inhibiting TLR signalling, IL-1 expression and the STAT-IL-6 signalling  pathway 94,207,209 . TcpC-deletion mutants showed reduced virulence in a mouse UTI model 206 , suggesting that bacteria are capable of attenuating the TLR-dependent host defence, but the therapeutic potential of TIR domain homologues has not been further explored.

The bacterial Lon protease is a MYC inhibitor
Transcriptional control of the innate immune response is essential, and targeting upstream transcriptional regulators such as IRF7 has a therapeutic potential. The pleiotropic transcription factor MYC controls the expression of about 60-70% of all genes, affecting metabolism, cell growth and survival and inflammatory networks [210][211][212] (Fig. 7). MYC is essential for renal development, guiding the fusion of ectoderm and endoderm and regulating renal growth 213,214 . Infants and children suffering from APN in childhood often show renal growth retardation, consistent with MYC inhibition by infection 215 (Fig. 7). Virulent UPEC strains have been shown to trigger MYC protein degradation and to inhibit the expression of MYC and MYC-related genes in a wide range of human cells 216 . MYC degradation was shown to be executed by the bacterial Lon protease, which enters human cells and animal tissues 216 . Treatment with recombinant Lon protease delayed cancer progression in models of bladder and colon cancer and increased long-term survival (Fig. 7), seemingly without any toxic response 216 . Furthermore, MYC regulated the renal response to infection by affecting the IRF3 and IRF7 transcription factors, suggesting that the protective potential of the MYC inhibitor in APN should be investigated 216 .

Competitive adherence inhibitors
Fimbriae-specific adherence to host cell receptors is competitively inhibited by soluble receptor analogues. Oligosaccharides that competitively inhibit adherence have shown protective effects in rodent UTI models 217,218 . Soluble glycolipid receptor antagonists have been shown to inhibit UPEC adhesion by occupying the P fimbrial adhesin PapG and have been shown to reduce bacterial numbers in the mouse UTI model 219,220 . Using a high-affinity inhibitory mannoside in C3H mice, a reduction in intestinal colonization of FimH and F17 fimbriated UPEC strains was shown while simultaneously protecting against UTIs 221 . No adverse effects on the intestinal microbiota were observed, suggesting a novel therapeutic approach to treating UTIs while leaving the microbiota unchanged. In early studies, α-methyl-d-mannose was shown to inhibit type 1 fimbrial binding to the bladder mucosa and affect cell shedding 161,217,222 . Inhibition of the FimH type 1 pilus lectin, was proposed to affect bacterial adherence, immune cell activation and the formation of intracellular bacterial communities in the mouse bladder epithelium 223 . An earlier study in a rat UTI model showed that low molecular-weight mannosides inhibit the bacterial adherence and persistence 218 . Oral treatment with active FimH inhibitors was non-inferior to trimethoprim-sulphamen toxazol in mediating bacterial www.nature.com/nrurol clearance from bladders in an infected UTI mouse model using C3H/HeN mice 224 . Thus, blocking bacterial adhesion might provide an interesting therapeutic strategy. Nearly all clinical cystitis isolates are FimH positive, but translation to clinical treatment has not been reported.
Vaccination strategies A number of antibacterial vaccination strategies have been successfully implemented, demonstrating that adaptive immunity can prevent infection by highly virulent organisms 225 . Vaccines prevent tetanus and diphtheria, as well as infections caused by Haemophilus influenzae and Streptococcus pneumoniae 225 . The awareness of vaccines and their crucial role for public health has increased dramatically, inspiring further attempts to prevent or treat infections by boosting adaptive immunity. Vaccination strategies are mostly designed to prevent infection, in contrast to innate immunomodulation therapy, which has been examined for therapeutic use.
Vaccination studies in UTI have a long history with varying results [226][227][228][229] . Early UTI vaccine studies targeted bacterial O-antigens expressed on LPS by the most virulent UPEC strains 226,230,231 . Clinical studies detected antibodies to a limited number of O-antigens in patients with APN but despite extensive studies in animal models, strong protective effects of vaccination were not observed 230 . Capsular polysaccharides were also tested as vaccine antigens, in analogy to the Haemophilus influenzae vaccine approach, but substantial protective effects were not achieved 231  Interesting vaccine studies have identified siderophores and their receptors as vaccine antigens that trigger a mucosal and systemic immune response and show promising results in mouse UTI models 229,234,243 . Siderophores are essential iron-acquisition molecules in UPEC strains and have an important role in UTI pathogenesis, enhancing bacterial virulence 71,154,244 . The potential of siderophores as vaccine antigens was investigated by adding the siderophores Ybt or Aer to the carrier protein cBSA 229 . A robust adaptive immune response was observed, with protection against bladder and kidney infection in the mouse 229 .
Potential vaccine candidates have further been selected from a pool of bacterial cell surface proteins expressed during growth in human urine, mouse infection models and confirmed in human infections 245,246 . Using an immunoproteomics approach, 23 outer-membrane proteins were shown to be immunoreactive 247 , including four that were prevalent among UPEC isolates 248,249 . Intranasal immunization with Hma, IutA, FyuA, or IreA, conjugated to cholera toxin, considerably reduced the bacterial burden in the bladder or kidneys after transurethral challenge with UPEC 234 . As cholera toxin is unsuitable for human use 250 , other mucosal adjuvants were tested for efficacy, including a double mutant heat-labile E. coli enterotoxin, dmLT 251 . Intranasal immunization with dmLT-Hma and dmLT-IutA induced antigen-specific antibody production and provided robust protection in immunized mice following transurethral challenge with UPEC 243 .
The recognition of bacterial adherence as a virulence factor, and secretory IgA antibodies as potent anti-adhesives in patient urine, suggested that mucosal vaccination could be feasible, using fimbriae as antigens 27,87,252 . Not limited by antigen recognition, secretory IgA possesses broad antibacterial function through  27,252 .
The vaccine concept has been advanced by using the FimH adhesin as the antigen 253 . In an open-label, dose-escalation phase I trial, 67 women with or without history of recurrent UTIs received intramuscular injections of FimH adhesin on four occasions. The drug was well tolerated with no serious adverse events reported and women with a history of UTIs had a 150-fold increase in FimH antibodies 254 . These preliminary positive data have led to FDA permission for compassionate use of the vaccine in patients with UTIs caused by multi drug-resistant E. coli 6 ; however, no data on therapeutic efficacy have been disclosed.
Classical questions and obstacles in triggering an adaptive immune response are the antigenic variation of the infecting bacterial strains, problems relating to defining pathogen-specific vaccine antigens, avoiding detrimental effects on the normal flora and identifying target populations suitable for different vaccine candidates. Most vaccination studies focus on creating a successful antibody response, and T cell responses in the bladder have previously received less attention 7 . However, macrophage depletion has been shown to promote T H 1-mediated responses and subsequent bacterial clearance while not affecting T H 2 responses 35 . These observations are supported by the results of a study that showed that bladder infection triggers a robust T H 2 cell response, causing re-epithelialization with a limited capacity to clear infection 255 . Furthermore, immunization with UPEC antigens combined with the T H 1-skewing adjuvant CpG was observed to protect mice from developing both single-episode and recurrent UTIs compared with untreated mice 256 . Intravesical vaccination provided a substantially better response than subcutaneous vaccination and was accompanied by an increase in local T H 1 cells. These results suggest that boosting T H 1 responses in the urinary tract might enhance protection. Controlled clinical trials are needed to define the protective potential of the different vaccination strategies.

Conclusions
This Review highlights the importance of innate immune control in UTI and the potential of innate immunomodulation therapy to target 'bad inflammation' as a cause of disease. This approach differs from the use of broad anti-inflammatory compounds, in that it seeks to correct specific innate immune defects in susceptible hosts. Potent therapeutic effects have been achieved in animal models, and patients with IC/BPS have responded favourably to off-label treatment with an IL-1RA 187 , but further studies are needed to understand the clinical potential of this approach. Controlled clinical trials are being initiated to improve understanding of the potential of IL-1RA treatment for ACY and important future target populations include patients with infections caused by antibiotic-resistant strains, in whom the need for new therapeutic options is immediately obvious.
Most previous studies of UTI pathogenesis and therapy have been conducted in animals without a clear disease phenotype or established human relevance. Genetic screens of mice with single gene deletions have now established that APN and ACY can be recreated, using single-gene deletions affecting innate immunity. Different innate immune defects distinguish APN from ACY, illustrating the molecular specificity for each organ system. Specific innate immunomodulatory therapeutic approaches have been designed to correct these defects and restore the defence. The disease phenotypes in mice were shown to share important features with human disease, suggesting that the translation of some of these findings into the clinic is of interest.
The finding of accelerated bacterial clearance in the kidneys of mice receiving Irf7 siRNA interference therapy is intriguing and partly unexpected. A similar effect was seen after IL-1RA treatment of ACY, suggesting that reducing inflammation restores immune balance and the antibacterial defence. The mechanisms are not entirely clear, but the findings suggest that the defence is impaired or overwhelmed by the excessive inflammatory response that accompanies disease. Despite a massive neutrophil infiltrate and hyperactive IRF7 or IL-1-dependent genes, the functionality of the defence seems to be lost. This effect was first observed in mCxcr2 −/− mice, in which neutrophil activation is impaired and defective exit across the mucosa into the urine creates massive neutrophil retention in the kidneys, leading to massive tissue damage 14,79,116 . The results also suggest that in addition to restored homeostasis, as yet undefined mechanisms of bacterial clearance might contribute to the resistance to infection in Irf7 −/− or Il1b −/− mice and immediate bacterial clearance from their tissues, a fascinating topic for further studies.
The strong effects of innate immunotherapy are promising, as they suggest new potential therapeutic solutions for the treatment of UTI and other bacterial infections. The early work on bacterial adherence and the identification of specific host cell receptors resulted in the realization that mucosal cells respond to infection and a number of host response parameters were identified, establishing the importance of innate immunity in UTI. Further characterization of signalling pathways and transcriptional regulators of the innate immune response led to the identification of specific defence dysfunctions and pinpointed exaggerated inflammation as the cause of acute, severe disease and tissue pathology. The control of these processes at the level of transcription and the involvement of individual transcription factors as arbitrators of protection or disease adds a new perspective. Adding the perspective that these mechanisms can be targeted to treat infection has provided convincing evidence that controlling the innate immune responses can be a potent alternative to antibiotics.

Published online 22 June 2022
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