Michael Eisenbach

Michael Eisenbach (Hebrew: מיכאל אייזנבך) is an Israeli biochemist who specializes in the navigation mechanisms of bacterial and sperm cells.^[1] He is a professor emeritus at the Weizmann Institute of Science, Department of Biomolecular Sciences, Rehovot, Israel.^[2] He discovered that sperm cells (spermatozoa) of mammals are actively guided to the egg. This opened the research field of mammalian sperm navigation (also termed sperm guidance). He demonstrated that the active navigation entails chemotaxis and thermotaxis.^[3] He made seminal contributions to the understanding of these two processes at the molecular, physiological and behavioural levels,^[3][4][5] as well as contributing to our understanding of the molecular mechanism of bacterial chemotaxis.^[6][7][8]

Michael Eisenbach
מיכאל אייזנבך
Born	(1945-04-10)April 10, 1945 Tel Aviv, Israel
Nationality	Israeli
Citizenship	Israel
Education	Ph.D., Tel Aviv University, 1975
Known for	Opening the field of mammalian sperm navigation, discovering mammalian sperm chemotaxis and thermotaxis, contributing to understanding of the molecular mechanism of bacterial chemotaxis
Scientific career
Fields	Biochemistry
Institutions	Weizmann Institute of Science
Website	www.weizmann.ac.il/Biomolecular_Sciences/Eisenbach/

Early life

Eisenbach was born in Tel Aviv, Israel on 10 April 1945. His parents, Menachem (Mendel; 1906–1976) and Haya (Helena Leibler; 1910–1993) Eisenbach, were born in Poland and immigrated to Israel at the end of 1934. Most of their family members remained in Poland and were exterminated in the Holocaust. Michael Eisenbach grew up in Tel Aviv and studied in an evening high school while working during the daytime as a messenger boy (first for the Tel Aviv-Yafo Municipality and then for the Dubek company). He served his compulsory military term in the Israel Defense Forces in 1963–1966.^[9]

Education

Eisenbach attended Tel Aviv University. He received his B.Sc. in chemistry (1969), M.Sc. (with distinction, 1971) and Ph.D. in biochemistry (1975). For his M.Sc., he studied, under the supervision of Chanoch Carmeli, the photosynthetic electron transport chain in chloroplasts.^[10] For his Ph.D., he studied, under the supervision of Menachem (Hemi) Gutman, the respiratory electron transport chain in mitochondria.^{[11][12][13][14]} He then moved to the Weizmann Institute of Science for postdoctoral study under the supervision of S. Roy Caplan, where he investigated the proton pump activity of bacteriorhodopsin in the purple membrane of archaea (1975–1978).^{[15][16][17][18][19][20]} He did a second postdoctoral fellowship in Madison, Wisconsin, USA where he studied bacterial chemotaxis under the supervision of Julius Adler^[21] (1978–1980).^[2]

Academic career

In 1980, Eisenbach returned to the Weizmann Institute as a senior scientist (equivalent to assistant professor) and established his own research group as an independent investigator. Four years later he was promoted to associate professor with tenure, and in 1995 to professor. In 2015, he became a professor emeritus.^[2]

Positions held

• Secretary of the Israel Society for Biochemistry (1989–1990)
• Chairman of the Department of Membrane Research and Biophysics (previously named Department of Membrane Research; currently named Department of Biomolecular Sciences), Weizmann Institute of Science (1989–1995)
• Chairman of the Israel National Committee for Microbiology, the Israel Academy of Sciences and Humanities (1992–2001)
• Director of the Josef Cohn Minerva Center for Biomembrane Research, Weizmann Institute of Science (1994–1999)
• Chairman of the advisory committee of the Aharon Katzir-Katchalsky Center, Weizmann Institute of Science (1996–1999)
• Chairman of the Scientific Council, Weizmann Institute of Science (2000–2002)
• Scientific Coordinator of Conseil Pasteur-Weizmann (2007–2012)
• President of the Israel Society for Biochemistry and Molecular Biology (2008–2011)
• Co-President of Conseil Pasteur-Weizmann (2012–2014)
• President of Conseil Pasteur-Weizmann (2014–2017)^[22]

Research

Mammalian sperm navigation

In the middle of his scientific career, Eisenbach initiated the research field of mammalian sperm navigation. This was in the early 1990s, when the prevailing consensus was that there is no need for sperm navigation in mammals.^[23] This idea was based on the very large number of spermatozoa ejaculated into the limited space of the female genital tract. However, the prevailing theory did not take into account that the number of spermatozoa that actually succeed in entering the fallopian tube is very small.^[3] With this background, Eisenbach’s group first found that human spermatozoa accumulate in diluted follicular fluid and that there is a remarkably strong correlation between the ability of follicular fluid from a particular follicle to cause sperm accumulation and the ability of the egg obtained from the same follicle to be fertilized.^{[24][25][23][26][27]} He then provided the first evidence that this sperm accumulation is the result of chemotaxis, accompanied by chemokinesis, and defined criteria for distinguishing chemotaxis from other processes that might cause sperm accumulation.^[28][29] His group further discovered that only a small fraction of the spermatozoa (~10% in humans) are chemotactically responsive and that the responsive spermatozoa are the capacitated ones (spermatozoa that have reached a maturation stage at which they can penetrate the egg and fertilize it).^[30][31] Whereas the capacitated state had generally been thought of as static, Eisenbach’s group found that the capacitated state is temporary (with a lifespan of 50–240 min for human spermatozoa in vitro), that there is a continuous process of replacement of capacitated spermatozoa within the sperm population, and that cells are phagocytized by macrophages once they lose their capacitation.^[31][32][33] He hypothesized,^[31] and then provided indirect evidence,^[34] that the physiological role of this continuous replacement of capacitated spermatozoa in humans is to prolong the availability of these spermatozoa to the egg during the relatively short time window when it resides in the fertilization site. His group then provided the first direct evidence that, subsequent to ovulation (i.e., outside the follicle), both the mature egg and its surrounding cumulus cells secrete chemoattractants^[35] and that progesterone is the main chemoattractant secreted from human cumulus cells.^[36]

Realizing that chemotaxis is a short-range process, operating over only a few millimetres,^[5] Eisenbach looked for a long-range navigation process and discovered thermotaxis. His group found that human, rabbit and mouse spermatozoa can navigate in a temperature gradient by thermotaxis and that, as in chemotaxis, only capacitated cells are thermotactically active.^{[37][38][39][40][41][4]} His group further found that, at ovulation, a shallow temperature gradient is established in the rabbit’s oviduct as a result of a temperature drop at the storage site,^[42] and that spermatozoa can respond thermotactically to such a shallow gradient.^[43] Indeed, his group found that the temperature sensitivity of human spermatozoa is so high that they can respond to a temperature difference of less than 0.0006 °C as they swim a body-length distance.^[43] Eisenbach’s group further identified the thermosensors for sperm thermotaxis and found that they are opsins, known to act as photosensors in vision.^[4] His group further provided evidence for two signaling pathways in sperm thermotaxis: the cyclic nucleotide pathway, triggered by rhodopsin, and the phospholipase C pathway, triggered by melanopsin and likely by other opsins.^[44][4][45]

Eisenbach’s group also revealed a major function of the motility type termed hyperactivation (a vigorous motility type, essential for fertilization, with characteristic large amplitudes of head displacement), and showed it to be a part of the behavioral mechanism of both sperm chemotaxis and thermotaxis in humans.^[46][47] Eisenbach further deciphered the behavioral mechanisms of both human sperm chemotaxis and thermotaxis, and showed that both are similar and based on modulation of the frequency of turns and hyperactivation events according to the gradient.^[46][47] He also demonstrated that human spermatozoa detect the chemoattractant concentration gradient in chemotaxis and the temperature gradient in thermotaxis temporally rather than spatially (namely, by comparing consecutive time points rather than comparing different locations).^[46][47] When Eisenbach realized that only capacitated spermatozoa are capable of active navigation, he proposed that, beyond guiding spermatozoa to the egg at the fertilization site, navigation competence also selects for capacitated spermatozoa,^[31] and that, therefore, sperm navigation can be used in artificial reproduction techniques to select capacitated spermatozoa, ripe for fertilization.^[48]

In 2004 a startup company, Repromed, was established with the aim of using thermotaxis to increase the success rate of artificial insemination.^[49] The company did not succeed, but a few years later, the concept was proven sound when a former postdoc of Eisenbach, Serafín Pérez-Cerezales, succeeded in demonstrating it.^[50]

Bacterial chemotaxis

Eisenbach’s first research area as an independent investigator, and one that he investigated throughout his career, was behavior at the molecular level, employing bacteria (primarily Escherichia coli and Salmonella) as a model system. Bacteria are attracted to some chemicals and repelled from others by chemotaxis.^[6] They do it by modulating the direction of flagellar rotation in response to changes in the concentrations of any of these chemicals, sensed by specific receptors. Eisenbach’s research group made fundamental discoveries in bacterial chemotaxis, contributing primarily to the understanding of the molecular mechanism by which the receptors communicate with the flagellar motor and the mechanism by which the motor changes its direction of rotation. His key achievements in this research area are as follows:

• Finding that the motor has a default direction of rotation and that, to initiate rotation in the other direction, a signal molecule — the cytoplasmic protein CheY — has to interact with the switch of the motor.^[51][52]
• Identifying the main binding site of CheY at the switch, the N-terminus of the switch protein FliM, and demonstrating that phosphorylation of CheY increases this binding and, consequently, enhances the rotation in the non-default direction.^[53][54][55]
• Discovering that the rotation-modulating activity of CheY is regulated not only by phosphorylation but also by acetylation.^[56][57][58]
• Revealing the molecular mechanism of CheY acetylation as well as the essential function that acetylated CheY fulfills in the motor’s switching mechanism.^{[59][60][61][62][63][64][8]}
• Uncovering the switching mechanism of the flagellar motor by identifying the processes that occur there subsequent to CheY binding to FliM.^[65][66][8]
• Discovering that fumarate is a switching factor in E. coli, identifying its target as the enzyme fumarate reductase, demonstrating that fumarate reductase binds to the switch protein FliG and forms a complex with the switch of the flagellar motor, and revealing the molecular mechanism by which fumarate binding to this complex triggers switching to the non-default direction of rotation.^{[67][68][69][70]}

Books

• Chemotaxis (515 pages) by Eisenbach, M. (2004), published by Imperial College Press, London.
• Sensing and Response in Microorganisms by Eisenbach, M. and Balaban, M. (1985), published by Elsevier Science Publishers, Amsterdam.

Personal life

Michael Eisenbach married Lea Eisenbach (née Abarbanel) in 1967, divorced in 1985, and married Michal Schwartz (née Hevrony) in 1991. He has three sons.

Eisenbach started learning to play the clarinet at the age of 70. In 2021, he became a member of the Maskit Clarinet Choir.^[71]

References

1. "Home | Eisenbach". www.weizmann.ac.il. Retrieved 2021-11-13.
2. Homepage - Michael Eisenbach (https://www.weizmann.ac.il/Biomolecular_Sciences/Eisenbach/) https://www.weizmann.ac.il
3. Eisenbach, M. and Giojalas, L.C. (2006) ‘’Sperm guidance in mammals - an unpaved road to the egg’’. Nat. Rev. Mol. Cell Biol. 7, 276–285.
4. Pérez-Cerezales, S., Boryshpolets, S., Afanzar, O., Brandis, A., Nevo, R., Kiss, V. and Eisenbach, M. (2015) ‘’Involvement of opsins in mammalian sperm thermotaxis.’’ Sci. Rep. 5, 16146.
5. Pérez-Cerezales, S., Boryshpolets, S. and Eisenbach, M. (2015) ‘’Behavioral mechanisms of mammalian sperm guidance’’. Asian J. Androl. 17, 628-632.
6. Eisenbach, M. (2004) “Chemotaxis” Imperial College Press, London
7. Eisenbach, M. (2007) “A hitchhiker’s guide through advances and conceptual changes in chemotaxis”. J. Cell. Physiol. 231, 574-580.
8. Afanzar O., Di Paolo D., Eisenstein M., Levi K., Plochowietz A., Kapanidis A. N., Berry R. M. and Eisenbach M. (2021) “The switching mechanism of the bacterial rotary motor combines tight regulation with inherent flexibility”. EMBO J. 40, e104683.
9. Peled-Harpaz, D. (2019) “Fifty thousandths of the millimeter” (in Hebrew). Hachaim Hatovim (August 2019) page 48.
10. Eisenbach, M. and Carmeli, C. (1974) “Sites along the electron-transport chain controlled by the energy-conversion system in chloroplasts”. Eur. J. Biochem. 37, 361-366.
11. Eisenbach, M. and Gutman, M. (1974) “Mid-potential measurements of an unidentified component, controlling the rate of reduction of the b-type cytochromes”. FEBS Lett. 46, 368-371.
12. Eisenbach, M. and Gutman, M. (1975) “Dynamic control on the rate of the reduction of the b-type cytochromes in submitochondrial particles”. Eur. J. Biochem. 52, 107-116.
13. Eisenbach, M. and Gutman, M. (1975) “Characterization of the component, which controls the transformation between the kinetic forms of the b cytochromes”. Eur. J. Biochem. 59, 223-230.
14. Eisenbach, M. and Gutman, M. (1976) “Demonstration of the active and sluggish forms of cytochrome b in isolated b-c1 complexes of the respiratory chain”. FEBS Lett. 61, 247-250.
15. Eisenbach, M., Bakker, E.P., Korenstein, R. and Caplan, S.R. (1976) “Bacteriorhodopsin: Biphasic kinetics of phototransients and of light-induced proton transfer in sub-bacterial Halobacterium halobium particles and in reconstituted liposomes”. FEBS Lett. 71, 228-232.
16. Eisenbach, M., Cooper, S., Garty, H., Johnstone, R.M., Rottenberg, H. and Caplan, S.R. (1977) “Light-driven sodium transport in sub-bacterial particles of Halobacterium halobium”. Biochim. Biophys. Acta 465, 599-613.
17. Eisenbach, M., Weissmann, C., Tanny, G. and Caplan, S.R. (1977) “Bacteriorhodopsin-loaded charged synthetic membranes: Utilization of light energy to generate electrical current”. FEBS Lett. 81, 77-80.
18. Eisenbach, M., Garty, H., Bakker, E.P., Klemperer, G., Rottenberg, H. and Caplan, S.R. (1978) “Kinetic analysis of light-induced pH changes in bacteriorhodopsin-containing particles from Halobacterium halobium”. Biochemistry 17, 4691-4698.
19. Eisenbach, M., Caplan, S.R. and Tanny, G. (1979) “Interaction of purple membrane with solvents: I. Applicability of solubility parameter mapping”. Biochim. Biophys. Acta 554, 269-280.
20. Eisenbach, M. and Caplan, S.R. (1979) “Interaction of purple membrane with solvents: II. Mode of interaction”. Biochim. Biophys. Acta 554, 281-292.
21. Eisenbach, M. and Adler, J. (1981) “Bacterial cell envelopes with functional flagella”. J. Biol. Chem. 256, 8807-8814.
22. "Weizmann Institute of Science, Michael Eisenbach Curriculum Vitae". Archived from the original on 9 December 2021. Retrieved 9 December 2021.
23. Aitken, J. (1991) “Do sperm find eggs attractive?” Nature 351, 19-20.
24. Ralt, D., Goldenberg, M., Fetterolf, P., Thompson, D., Dor, J., Mashiach, S., Garbers, D.L. and Eisenbach, M. (1991) “Sperm attraction to follicular factor(s) correlates with human egg fertilizability”. Proc. Natl. Acad. Sci. U.S.A. 88, 2840-2844.
25. Roberts, L. (1991) “Does egg beckon sperm when the time is right?” Science 252, 214.
26. Ezzel, C. (1991) “Eggs not silent partners in conception”. Science News 139, 214.
27. The Washington Post (April 1, 1991) front page, The Wall Street Journal (April 1, 1991), The New York Times (April 2, 1991), Los Angeles Times (April 1, 1991).
28. Ralt, D., Manor, M., Cohen-Dayag, A., Tur-Kaspa, I., Makler, A., Yuli, I., Dor, J., Blumberg, S., Mashiach, S. and Eisenbach, M. (1994) ‘’Chemotaxis and chemokinesis of human spermatozoa to follicular factors’’. Biol. Reprod. 50, 774–785.
29. Eisenbach, M. (1999) “Sperm chemotaxis”. Rev. Reprod. 4, 56-66.
30. Cohen-Dayag, A., Ralt, D., Tur-Kaspa, I., Manor, M., Makler, A., Dor, J., Mashiach, S. and Eisenbach, M. (1994) ‘’Sequential acquisition of chemotactic responsiveness by human spermatozoa’’. Biol. Reprod. 50, 786–790.
31. Cohen-Dayag, A., Tur-Kaspa, I., Dor, J., Mashiach, S. and Eisenbach, M. (1995) ‘’Sperm capacitation in humans is transient and correlates with chemotactic responsiveness to follicular factors’’. Proc. Natl. Acad. Sci. U.S.A. 92, 11039–11043.
32. Eisenbach, M. (2003) “Why are sperm cells phagocytosed by leukocytes in the female genital tract?” Med. Hypoth. 60, 590-592.
33. Oren-Benaroya, R., Kipnis, J. and Eisenbach, M. (2007) “Phagocytosis of human post-capacitated spermatozoa by macrophages”. Hum. Reprod. 22, 2947-2955.
34. Giojalas, L.C., Rovasio, R.A., Fabro, G., Gakamsky, A. and Eisenbach, M. (2004) “Timing of sperm capacitation appears to be programmed according to egg availability in the female genital tract”. Fertil. Steril. 82, 247-249.
35. Sun F., Bahat A., Gakamsky A., Girsh E., Katz N., Giojalas L. C., Tur-Kaspa, I. and Eisenbach, M. (2005) “Human sperm chemotaxis: Both the oocyte and its surrounding cumulus cells secrete sperm chemoattractants”. Hum. Reprod. 20, 761-767.
36. Oren-Benaroya, R., Orvieto, R., Gakamsky, A., Pinchasov, M. and Eisenbach, M. (2008) “The sperm chemoattractant secreted from human cumulus cells is progesterone”. Hum. Reprod. 23, 2339-2345.
37. Bahat, A., Tur-Kaspa, I., Gakamsky, A., Giojalas, L.C., Breitbart, H. and Eisenbach, M. (2003) “Thermotaxis of mammalian sperm cells: A potential navigation mechanism in the female genital tract”. Nat. Med. 9, 149–150.
38. Beckman, M. (2003) “Sperm like it hot”. Science online (Science doi: 10.1126/article.35558).
39. Pearson, H. (2003) “Sperm like it hot”. Nature online (Nature doi:10.1038/news030127-14).
40. Travis, J. (2003) “Heat-seeking missiles”. Science News 163, 69.
41. Weinstock, M. (2003) “Race to the egg”. Discover (July 2003) 16.
42. Bahat, A., Eisenbach, M. and Tur-Kaspa, I. (2005) “Periovulatory increase in temperature difference within the rabbit oviduct”. Hum. Reprod. 20, 2118-2121.
43. Bahat, A., Caplan, S.R. and Eisenbach, M. (2012) “Thermotaxis of human sperm cells in extraordinarily shallow temperature gradients over a wide range”. PLoS ONE 7, e41915.
44. Bahat, A. and Eisenbach, M. (2010) “Human sperm thermotaxis is mediated by phospholipase C and inositol trisphosphate receptor Ca²⁺ channel”. Biol. Reprod. 82, 606-616.
45. Roy, D., Levi, K., Kiss, V., Nevo R. and Eisenbach, M. (2020) “Rhodopsin and melanopsin coexist in mammalian sperm cells and activate different signaling pathways for thermotaxis”. Sci. Rep. 10, 112.
46. Armon, L. and Eisenbach, M. (2011) “Behavioral mechanism during human sperm chemotaxis: Involvement of hyperactivation”. PLoS ONE 6, e28359.
47. Boryshpolets, S., Pérez-Cerezales, S. and Eisenbach, M. (2015) “Behavioral mechanism of human sperm in thermotaxis — a role for hyperactivation.” Hum. Reprod. 30, 884-892.
48. For example, patents US5849713, EP0679091B1, CA2540156C.
49. "RelSci | the Relationship Capital Platform | Relationship Science".
50. Pérez-Cerezales, S., Laguna-Barraza, R., Chacón de Castro, A., Sánchez-Calabuig, M.J., Cano-Oliva, E, Javier de Castro-Pita, F., Montoro-Buils, L., Pericuesta, E., Fernández-González, R. and Gutiérrez-Adán, A. (2018) “Sperm selection by thermotaxis improves ICSI outcome in mice”. Sci. Rep. 8, 2902.
51. Ravid S. and Eisenbach, M. (1984) “Direction of flagellar rotation in bacterial cell envelopes”. J. Bacteriol. 158, 222-230.
52. Ravid, S., Matsumura, P. and Eisenbach, M. (1986) “Restoration of flagellar clockwise rotation in bacterial envelopes by insertion of the chemotaxis protein CheY”. Proc. Natl. Acad. Sci. U.S.A. 83, 7157-7161.
53. Barak, R. and Eisenbach, M. (1992) “Correlation between phosphorylation of the chemotaxis protein CheY and its activity at the flagellar motor”. Biochemistry, 31, 1821-1826.
54. Welch, M., Oosawa, K., Aizawa, S.-I. and Eisenbach, M. (1993) “Phosphorylation-dependent binding of a signal molecule to the flagellar switch of bacteria”. Proc. Natl. Acad. Sci. U.S.A. 90, 8787-8791.
55. Bren, A. and Eisenbach, M. (1998) “The N terminus of the flagellar switch protein, FliM, is the binding domain for the chemotactic response regulator, CheY”. J. Mol. Biol. 278, 507-514.
56. Barak, R., Welch, M., Yanovsky, A., Oosawa, K. and Eisenbach, M. (1992) “Acetyladenylate or its derivative acetylates the chemotaxis protein CheY in vitro and increases its activity at the flagellar switch”. Biochemistry, 31, 10099-10107.
57. Barak, R., Abouhamad, W.N. and Eisenbach, M. (1998) “Both acetate kinase and acetyl Coenzyme A synthetase are involved in acetate-stimulated change in the direction of flagellar rotation in Escherichia coli”. J. Bacteriol. 180, 985-988.
58. Barak, R. and Eisenbach, M. (2001) “Acetylation of the response regulator, CheY, is involved in bacterial chemotaxis”. Mol. Microbiol. 40, 731-743.
59. Barak, R., Prasad, K., Shainskaya, A., Wolfe, A. J. and Eisenbach, M. (2004) “Acetylation of the chemotaxis response regulator CheY by acetyl-CoA synthetase from Escherichia coli”. J. Mol. Biol. 342, 383-401.
60. Barak, R. and Eisenbach, M. (2004) “Co-regulation of acetylation and phosphorylation of CheY, a response regulator in chemotaxis of Escherichia coli”. J. Mol. Biol. 342, 375-381.
61. Barak, R., Yan, J., Shainskaya, A. and Eisenbach, M. (2006) “The chemotaxis response regulator CheY can catalyze its own acetylation”. J. Mol. Biol. 359, 251-265.
62. Yan, J., Barak, R., Liarzi, O., Shainskaya, A. and Eisenbach, M. (2008) “In vivo acetylation of CheY, a response regulator in chemotaxis of Escherichia coli”. J. Mol. Biol. 376, 1260-1271.
63. Liarzi, O., Barak, R., Bronner, V., Dines, M., Sagi, Y., Shainskaya, A. and Eisenbach, M. (2010) “Acetylation represses the binding of CheY to its target proteins”. Mol. Microbiol. 76, 932-943.
64. Fraiberg, M., Afanzar, O., Cassidy, C.K., Gabashvili, A., Schulten, K., Levin, Y. and Eisenbach M. (2015) “CheY’s acetylation sites responsible for generating clockwise flagellar rotation in Escherichia coli”. Mol. Microbiol. 95, 231-244.
65. Bren, A. and Eisenbach, M. (2001) “Changing the direction of flagellar rotation in bacteria by modulating the ratio between the rotational states of the switch protein FliM”. J. Mol. Biol. 312, 699-709.
66. Sagi, Y., Khan, S. and Eisenbach, M. (2003) “Binding of the chemotaxis response regulator CheY to the isolated, intact switch complex of the bacterial flagellar motor: Lack of cooperativity”. J. Biol. Chem. 278, 25867-25871.
67. Barak, R. and Eisenbach, M. (1992) “Fumarate or a fumarate metabolite restores switching ability to rotating flagella of bacterial envelopes”. J. Bacteriol., 174, 643-645.
68. Prasad, K., Caplan, S.R. and Eisenbach, M. (1998) “Fumarate modulates bacterial flagellar rotation by lowering the free energy difference between the clockwise and counterclockwise states of the motor”. J. Mol. Biol. 280, 821-828.
69. Cohen-Ben-Lulu, G.N., Francis, N.R., Shimoni, E., Noy, D., Davidov, Y., Prasad, K., Sagi, Y., Cecchini, G., Johnstone, R.M. and Eisenbach, M. (2008) “The bacterial flagellar switch complex is getting more complex”. EMBO J. 27, 1134-1144.
70. Koganitsky, A., Tworowski, D., Dadosh, T., Cecchini, G. and Eisenbach, M. (2019) “A Mechanism of Modulating the Direction of Flagellar Rotation in Bacteria by Fumarate and Fumarate Reductase”. J. Mol. Biol. 431, 3662–3676.
71. "Home". clarinet-choir.org.

External links

• Eisenbach’s website
• Michael Eisenbach publications indexed by Google Scholar