Sammy Boussiba

Sammy Boussiba

Sammy Boussiba
Born (1947-08-30) 30 August 1947
Fes, Morocco
Nationality Israeli
Fields Microalgae
Institutions Ben-Gurion University of the Negev
Alma mater Ben-Gurion University of the Negev
Doctoral advisor Amos Richmond

Sammy Boussiba is a Professor Emeritus at the French Associates Institute for Agriculture and Biotechnology of Drylands at the Jacob Blaustein Institutes for Desert Research at Ben-Gurion University of the Negev, Israel.

Early life

Sammy Boussiba was born in Fez, Morocco to a Jewish family. In 1956 he emigrated to Israel with his parents and two brothers. He began his academic path in 1969, and received his Bachelor's and Master's degrees from the Hebrew University of Jerusalem and from BGU. He moved on to his doctorate studies at BGU, focusing on the role of the biliprotein picocyanin C and the influence of environmental factors on its metabolism, under the supervision of Prof. Amos Richmond. He completed his PhD in 1981 and continued to his post-doctoral studies at Cornell University, with scholarships from the Rothschild and Fullbright Foundations. At Cornell he studied the uptake and metabolism of ammonia in cyanobacteria.

Academic career

In 1984, upon completing his post doctoral studies and returning to Israel, Boussiba joined the Microalgal Biotechnology Laboratory (MBL) at Jacob Blaustein Institutes for Desert Research BIDR, BGU. He has served as the head of the lab since 1995.[1] During the years 2001-2005 he also served as the substitute to the Director of BIDR and during the years 2008-2015 he served as director of the French Associates Institute for Agriculture and Biotechnology of Drylands at BIDR.

Awards

In 2003 Boussiba was awarded an honorary doctorate ("Honoris Causa") from the University of West Hungary, which was the first European University to establish an Agriculture Faculty.[2] He was bestowed with the economical botanics chair from BGU. Since 2004 he has served in the board of directors of the International Society of Applied Phycology.[3] In 2005 he was elected as the president of the Society, and also served as its president between the years 2008-2011. In a conference which took place in Australia in June 2014, Prof. Boussiba received a special award of appreciation from this Society, for his continual and outstanding contribution to the field of applied phycology research. Between the years 2009-12 Prof. Boussiba served as a member of the board of directors at the Inter-University marine biology and biotechnology Institute in Eilat. In 2009 he was elected for an Ad-Hoc committee nominated by the National Science Academy of the USA, aimed at examining the sustainable development of algal fuels and oils,[4] in which he served for two years. The committee's conclusions were published in a report aiming to formulate the USA government's policy on alternative fuels.[5] Since 2009 Prof. Boussiba has also served as a member of the European Algae Biomass Association EABA, and since 2014 he has served as the head of its scientific board.[6]

Research

Production of astaxanthin from the haematococcus microalgae:[7] The Haematococcus Pluvialis microalgae has been extensively researched for its ability to accumulate large quantities of the astaxanthin pigment, which is a potent naturally occurring anti-oxidant.[8] A synthetic version of this pigment is currently used for obtaining pink-colored salmon fish for marketing.[9] The production of this pigment in Haematococcus Pluvialis is enhanced due to various environmental stresses which limit the growth of the cell under light conditions. The production process is characterized by a transition in the cell’s color from green to red, along with various chemical and biochemical changes within the cell which have been widely studied in recent years: defining the conditions under which the pigment is accumulated, studying the biosynthetic process; and examining the possible role of the pigment in protecting the cell from oxidative stress damage. One outcome of this work was the development of a two-stage process for production of astaxanthin – the algae is allowed to grow under optimal conditions for the green stage, then the biomass is subjected to stress conditions such as high light or nutrient deprivation.

One of the main challenges in large-scale production of biomass is the susceptibility to infections, especially when the growth medium is poor in nutrients- enabling the growth of various fungi and foreign algae. Indeed, one of the main pests which can cause the collapse of the Haematococcus Pluvialis culture is a fungus. In Prof. Boussiba’s lab this fungus has been researched and isolated and defined as a new species (Paraphyzoderma Sedebokerensis[10]). This fungi is a specific parasite for Haematococci cells. Following its cultivation under sterile conditions, its life cycle was defined and its mode of infection was studied. Results showed that there are special proteins (lectins) present on the zeospheres of the fungi which recognize specific sugar moieties upon the algal cell wall. The infection process begins with the interaction between the lectins and the sugar moieties, and can end with the collapse of the algae culture.

Prof. Boussiba’s researches, spanning over ten years of work, were the basis for the establishment of an astaxanthin production plant from the Haematococcus microalgae in Kibbutz Ketura in the Arava valley - Algatech, which has been active since 2002.[11]

Cloning of Bti bacterial genes into the Anabaena cyanobacteria for eradication of tropical diseases: The Bacillus thuringiensis (Bt) group of bacteria is an important agent used for biological pest control. Bt is a Gram positive, aerobic bacterium which during its sporulation stage produces an endotoxin protein crystal with high toxicity and specificity against various insect larvae. Bt toxins are termed insecticidal crystal proteins (ICPs) and are active within the intestine, thus must be digested by the target organism in order to act. The subspecies Bacillus thuringienesis israelensis (Bti) was isolated by Prof. Joel Margalit and colleagues (1977). It is a specific pesticide of mosquito larvae and of black flies, which transfer a large number of tropical, sometimes fatal diseases. This subspecies produces a crystal composed of four main proteins encoded by four genes which are situated on a single plasmid within the bacterium. However, the use of Bti as a biological pesticide is limited due to its low survivability rate in natural water ponds. One of the ways to overcome the survivability hurdle is to clone the genes encoding for the toxin into other organisms which are more adapted to the harsh environments in question. Due to their large species diversity and high abundancy in natural ponds and rice fields, cyanobacteria have high potential to serve as carriers for the endotoxin genes for pest control of mosquito larvae. Moreover, cyanobacteria are able to float in the upper layer of the water, and are stable under varying environmental conditions, as well as throughout entire growth cycles of the mosquitos, which feed off the cyanobacteria. The most lethal combination of Bti genes was cloned in Prof. Boussiba’s laboratory in the Anabaena PCC 7120 cyanobacteria.[12][13] This pioneering work yielded a transgenic cyanobacteria stably expressing four different Bti genes. The transgenic lines are very stable and are of high toxicity to the larvae. Moreover they survived under field conditions for longer periods of time than the commercially available Bti pesticide. Since these clones are considered genetically modified organisms (GMO), the widespread use of this technology is still limited. This project, which lasted for several years, included the training of many research students and several prestigious research grants were obtained for it. This project is an example for the fruitful cooperation between two groups which are leading in their field – Prof. Zaritsky’s lab and Prof. Boussiba’s, where the transgenic cyanobacteria were isolated.

In recent years Prof. Boussiba’s researches are focusing on genetic methods for improving microalgae in aim to produce valuable products such as carotenoids and PUFA – polyunsaturated fatty acids.[14] One of the results of these researches is the development of a genetic engineering system for inserting genes into the genomes of two microalgal species of high economical value – Haematococcus Pluvialis for increasing the production rate of astaxanthin, and Parietochloris Incisa – for metabolic engineering of PUFA. Prof. Boussiba has led research projects in cooperation with researchers in Israel and worldwide, and during recent years he has been a partner in a large number of projects under the umbrella of the FP7 program of the European Union. He recently (2010-2013) managed the GIAVAP project- Genetically improved Algae for Valuable Products,[15][16] in which ten European and two industrial companies from Israel and from abroad took part. This project was aimed at genetic modification of microalgae for production of valuable (5.4 MEuro) products.[17] Prof. Boussiba is also a partner of the Israeli consortium for solar fuels, of the Israeli Centers of Research Excellence – ICORE,[18] for which Ben-Gurion University was awarded with 3 million sheqels over the years 2012-2016. At the end of 2015 his lab received an additional grant of 1.7 million sheqels over three years from the Israeli Ministry of Agriculture, for developing an innovative system for vaccinating poultry against the Newcastle Disease, using genetically modified microalgae.

Selected articles

References

  1. "Microalgal Biofuels Production". in.bgu.ac.il. Retrieved 2016-11-17.
  2. "Sustainable Development of Algal Biofuels in the United States".
  3. "International Society for Applied Phycology executive committee".
  4. "Committee Membership - Sustainable Development of Algal Biofuels in the United States". dels.nas.edu. Retrieved 2016-11-17.
  5. Council, National Research (2012-10-24). Sustainable Development of Algal Biofuels in the United States. doi:10.17226/13437. ISBN 9780309260329.
  6. BYDAS. "GOVERNING BODIES | EABA". EABA - European Algae Biomass Association. Retrieved 2016-11-17.
  7. "Professor Sammy Boussiba of the Microalgal Biotechnology Laboratory in the Ben Gurion University of Negev has developed the biotechnology of producing astaxanthin-rich Haematococcus pluvialis biomass.".
  8. Shah, Md Mahfuzur R.; Liang, Yuanmei; Cheng, Jay J.; Daroch, Maurycy (2016-01-01). "Astaxanthin-Producing Green Microalga Haematococcus pluvialis: From Single Cell to High Value Commercial Products". Plant Biotechnology: 531. doi:10.3389/fpls.2016.00531. PMC 4848535Freely accessible. PMID 27200009.
  9. "An algae researcher in Israel was one of the first in the world to develop a natural version of salmon colorant, based on algae".
  10. Gutman, Jenia; Zarka, Aliza; Boussiba, Sammy (2011-08-01). "Evidence for the involvement of surface carbohydrates in the recognition of Haematococcus pluvialis by the parasitic blastoclad Paraphysoderma sedebokerensis". Fungal Biology. 115 (8): 803–811. doi:10.1016/j.funbio.2011.06.006. ISSN 1878-6146. PMID 21802061.
  11. "Algatechnologies establishes a pilot plant in Kibbutz Ketura, and commercializes the work of Prof. Sammy Boussiba from the Sde Boker Research Institute of Ben-Gurion University of the Negev".
  12. "Genetic Engineering of Cyanobacteria".
  13. Khasdan, Vadim; Ben-Dov, Eitan; Manasherob, Robert; Boussiba, Sammy; Zaritsky, Arieh (2003-10-24). "Mosquito larvicidal activity of transgenic Anabaena PCC 7120 expressing toxin genes from Bacillus thuringiensis subsp. israelensis". FEMS microbiology letters. 227 (2): 189–195. ISSN 0378-1097. PMID 14592708.
  14. "Advances in the production of High Value Products by Microalgae: Current Status and Future Prospectives" (PDF).
  15. "GIAVAP Modification of marine or freshwater algae to better suit industrial applications" (PDF).
  16. "European Commission : CORDIS : Projects & Results Service : Final Report Summary - GIAVAP (Genetic Improvement of Algae for Value Added Products)". cordis.europa.eu. Retrieved 2016-11-17.
  17. "European Commission : CORDIS : Projects & Results Service : Algae for value-added products". cordis.europa.eu. Retrieved 2016-11-17.
  18. "I-CORE - Israeli Centers Of Research Excellence". www.i-core.org.il. Retrieved 2016-11-17.

External links

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