TY - JOUR
T1 - Evidence for bistable bacteria-neutrophil interaction and its clinical implications
AU - Malka, Roy
AU - Wolach, Baruch
AU - Gavrieli, Ronit
AU - Shochat, Eliezer
AU - Rom-Kedar, Vered
N1 - Israel Science Foundation [273/07]; Minerva FoundationThe authors thank Yakar Kannai and Elchanan Mossel for helpful discussions and Dirk Roos and John Higgins for comments on this manuscript. This work was partially supported by the Israel Science Foundation (grant 273/07) and the Minerva Foundation. V. Rom-Kedar is the Estrin Family Chair of Computer Science and Applied Mathematics at Weizmann Institute of Science.
PY - 2012/8/1
Y1 - 2012/8/1
N2 - Neutropenia, which may develop as a consequence of chemotherapy, increases the risk of bacterial infection. Similarly, increased risk of bacterial infection appears in disorders of phagocytic functions, such as the genetic disorder chronic granulomatous disease. To elucidate the organizing principles behind these distinct immunodeficiency conditions, we investigated the interaction between in vitro bacteria and human neutrophils by experiments and mathematical modeling. The model and the experiments showed that the in vitro bacterial dynamics exhibit bistability for a certain range of neutrophil concentration and function. Thus, there is a critical bacterial concentration above which infection develops, and below which neutrophils defeat the bacteria. Whereas with normal neutrophil concentration and function, an infection may develop when the initial bacterial concentration is very high, under neutropenic conditions or when there is neutrophil dysfunction, the critical bacterial concentration can be lower, within the clinically relevant range. We conclude that critical bacterial concentration has clinically relevant implications. The individual maximum bearable bacterial concentration depended on neutrophil concentration, phagocytic activity, and patient barrier integrity; thus, the resulting maximal bearable bacterial concentration may vary by orders of magnitude between patients. Understanding the interplay between neutrophils and bacteria may enhance the development of new therapeutic approaches to bacterial infections.
AB - Neutropenia, which may develop as a consequence of chemotherapy, increases the risk of bacterial infection. Similarly, increased risk of bacterial infection appears in disorders of phagocytic functions, such as the genetic disorder chronic granulomatous disease. To elucidate the organizing principles behind these distinct immunodeficiency conditions, we investigated the interaction between in vitro bacteria and human neutrophils by experiments and mathematical modeling. The model and the experiments showed that the in vitro bacterial dynamics exhibit bistability for a certain range of neutrophil concentration and function. Thus, there is a critical bacterial concentration above which infection develops, and below which neutrophils defeat the bacteria. Whereas with normal neutrophil concentration and function, an infection may develop when the initial bacterial concentration is very high, under neutropenic conditions or when there is neutrophil dysfunction, the critical bacterial concentration can be lower, within the clinically relevant range. We conclude that critical bacterial concentration has clinically relevant implications. The individual maximum bearable bacterial concentration depended on neutrophil concentration, phagocytic activity, and patient barrier integrity; thus, the resulting maximal bearable bacterial concentration may vary by orders of magnitude between patients. Understanding the interplay between neutrophils and bacteria may enhance the development of new therapeutic approaches to bacterial infections.
UR - http://www.scopus.com/inward/record.url?scp=84864742222&partnerID=8YFLogxK
U2 - https://doi.org/10.1172/JCI59832
DO - https://doi.org/10.1172/JCI59832
M3 - مقالة
SN - 0021-9738
VL - 122
SP - 3002
EP - 3011
JO - Journal of Clinical Investigation
JF - Journal of Clinical Investigation
IS - 8
ER -