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In humans, macrophages are targeted by Y. pestis, the causative agent of plague, and are therefore important for successful infection. We tested whether Ccr5 affects the uptake of Y. pestis by macrophages in vitro by using peritoneal macrophages from Ccr5+/+ and Ccr5−/− mice in phagocytosis assays. The uptake by Ccr5−/− macrophages was about 30-fold lower than that by Ccr5+/+ macrophages (Fig. 1a; six independent experiments). Our preliminary results indicate that the uptake of Yersinia pseudotuberculosis by macrophages from Ccr5−/− mice is much less inhibited in similar experiments (Fig. 1b), suggesting that the inhibition may be specific to Y. pestis.

Figure 1: Ccr5 influence on the uptake of bacteria by macrophages in vitro and on the survival of mice infected with Yersinia pestis.
figure 1

a, b, The intracellular bacteria recovered from peritoneal macrophages isolated from C57BL/6 Ccr5+/+ and Ccr5−/− mice and incubated (1×106 cells for 1 h at 37°C) with a, Y. pestis GB (multiplicity of infection, 10 colony-forming units (CFU); mean±s.e.m.) or b, Y. pseudotuberculosis strain IP32953. Gentamycin was used to kill extracellular bacteria. c, Survival of C57BL/6 Ccr5+/+ mice (blue; n = 9) and Ccr5−/− mice (orange; n = 10) after challenge with 2 CFU Y. pestis GB (Biovar orientalis, Pgm+, LcrV+; median lethal dose is 1 CFU) subcutaneously.

To test the effect of Ccr5 on survival after Y. pestis infection, groups of specific pathogen-free Ccr5+/+ and Ccr5−/− mice were challenged with lethal inocula of Y. pestis GB, a highly virulent strain isolated from a fatal human case of plague. However, there was no significant difference in survival between the groups, even after infection with a low dose of two colony-forming units (CFU) (Fig. 1c).

Our survival data are in agreement with those of Mecsas et al.1, although we used a strain of Y. pestis with a different degree of virulence (GB rather than KIM), mice with a different genetic background (C57BL/6 rather than BALB/c) and a different route of infection (subcutaneous rather than intravenous). Our results show that Ccr5−/− mice are not protected against infection with a fatal human isolate of Y. pestis and succumb at the same rate as Ccr5+/+ mice.

Although these results seem to disprove the ‘plague hypothesis’, some doubts remain. We consistently observed a marked reduction in the uptake of Y. pestis by Ccr5−/− macrophages in vitro that appears to be specific to this species of Yersinia. The Y. pestis strain that caused the great plague pandemic in the fourteenth century was probably quite different from the twentieth-century isolate used for the infection experiments discussed here. Genome analysis indicates that Y. pestis evolved rapidly from an enteric organism, which was spread by the faecal–oral route, to a flea-transmitted pathogen of rodents and humans, with acquisition of novel virulence mechanisms along the way8,9.

In addition, the pathogenesis of Y. pestis infection may not be comparable when delivered by injection of mice in the laboratory rather than by flea-borne transmission to humans10, because infection may be more rapid and acute. The dose of plague bacteria delivered by flea-borne transmission is likely to be more variable and the outcome of infection to depend on an interaction between the pathogen, vector and mammalian host. A previous infection leading to preactivation of the host's immune system would change the course of a subsequent Y. pestis infection — as would be expected in people living in the Middle Ages, who were constantly encountering all kinds of infection and in whom a resistance to plague could have developed in association with the CCR5Δ32 mutation.

Under these circumstances, firm conclusions cannot be drawn from the negative results obtained in Ccr5-deficient mice. Taking all these arguments into consideration, the data on the role of CCR5 in Y. pestis infection are still inconclusive because the situation seems to be more complex than previously anticipated.