Sydney Brenner was born in South Africa (13 January 1927) and educated at the University of Witwatersrand, Johannesburg (Medicine and Science). He studied at Oxford University and received a degree of D.Phil., in 1952 working in the Physical Chemistry Laboratory. After a brief return to South Africa he joined the Medical Research Council (MRC) unit in the Cavendish Laboratory in Cambridge in 1956. He worked in it and its successor, the MRC Laboratory of Molecular Biology in Cambridge where he was the Director from 1979 to 1987. In 1987 he became Director of the MRC Unit of Molecular Genetics retiring in 1992 from the MRC. He is now the Director of the Molecular Sciences Institute, a private research institute in Berkeley, California.
His early research was in molecular genetics, working with bacterophages and bacteria; he discovered messenger RNA (with Jacob and Meselson) and, with Francis Crick, showed that the code was composed of triplets.
In the sixties, he changed directions and initiated his research on Caenorhabditis elegans establishing it as a powerful experimental system for the analysis of complex biological process. As a geneticist, he saw that the techniques of cloning and sequencing would open up new ways of approaching genetics and he turned to studying vertebrate genomics and has established the pufferfish genome as a powerful tool in genome analysis. His foresight, enthusiasm and leadership are described vividly in "In The Beginning Was The Worm" (Brown, 2003).
Brown, A. 2003. In the Beginning Was the Worm. Simon & Schuster, London. 244p.
Most people, if they're lucky, get to retire once. Sydney Brenner, a giant in molecular biology, has just begun his second retirement, and now it looks like he'll have a shot at a third. Mr. Brenner, who turns 74 this month, has stepped down as president and director of science at the Molecular Sciences Institute in Berkeley, Calif. -- a job he came out of retirement to take in 1996. But he couldn't resist accepting an offer to become a distinguished research professor at the Salk Institute for Biological Studies, partly because it, like Mr. Brenner's home, is in La Jolla, Calif. "It is very good to have young people to talk to and listen to," says Mr. Brenner, adding that the interaction at the Salk Institute will do him good while he focuses on writing a book about the next step in research on the human genome. The book is to be published later this year by Princeton University Press. Mr. Brenner, who was born in South Africa, spent the bulk of his 50-year career in Cambridge, England, where he directed the Laboratory of Molecular Biology. He retired in 1992 -- and then was lured to Berkeley. But the Molecular Sciences Institute's endowment runs out in July, and Mr. Brenner says he didn't want to have to raise more money to keep it going. "I don't want to be the head of a large organization and just push paper and people every day," he says. But he adds: "I don't want to retire to play golf. Science is one's hobby and one's work and one's pleasure." Mr. Brenner is best known for his work in the 1960's, which established the existence of messenger RNA, which transmits information from DNA to proteins. That discovery won him the prestigious Lasker Award in 1971 for basic medical research. More recently, he has been part of a team studying vertebrate genome evolution using the Japanese puffer fish. Mr. Brenner won a second Lasker award last fall for work in medical sciences, honoring his achievements over a lifetime. "The first one was for science," Mr. Brenner cracks, "the next one was for surviving."
In late 1962, Francis Crick and I began a long series of conversations about the next steps to be taken in our research. Both of us felt very strongly that most of the classical problems of molecular biology had been solved and that the future lay in tackling more complex biological problems. I remember that we decided against working on animal viruses, on the structure of ribosomes, on membranes, and other similar trivial problems in molecular biology. I had come to believe that most of molecular biology had become inevitable and that, as I put it in a draft paper, "we must move on to other problems of biology which are new, mysterious and exciting. Broadly speaking, the fields which we should now enter are development and the nervous system." At that time, there were extensive discussions with the Medical Research Council on building an extension to the Laboratory, and Max Perutz, the head of our laboratory, had been exploring the ground with the Council. I have recently found the correspondence on this topic, and in a letter dated 5 June, 1963 (see below), I wrote to Max and explained my views to him. Nematodes have not yet made their appearance, because I had only just started to read about them and had not yet formulated any ideas. Some people thought that our approach was too "biological" and would lead us away from molecular biology, but, in any event, we were asked to make a formal proposal, and a document was accordingly submitted to the Council in October, 1963. During the summer I had formulated my ideas, and as you will see from the document and the Appendix referred to, the now familiar lines of the project had emerged. Note that the paper refers to C. briggsae; it was some time before Caenorhabditis elegans was selected in preference.
I hope readers will enjoy the last, brief paragraph of the Appendix. They should understand that it has expanded into the contents of this book, and achieving it has taken more than 20 years and the labors of a large number of people.
From The Nematode Caenorhabditis elegans, WB Wood and the community of C elegans researchers, eds., Cold Spring Harbor Laboratory Press, Cold Spring Harbor, 1988.
5 June, 1963
These notes record and extend our discussions on the possible expansion of research activities in the Molecular Biology Laboratory.
First, some general remarks. It is now widely realized that nearly all the "classical" problems of molecular biology have either been solved or will be solved in the next decade. The entry of large numbers of American and other biochemists into the field will ensure that all the chemical details of replication and transcription will be elucidated. Because of this, I have long felt that the future of molecular biology lies in the extension of research to other fields of biology, notably development and the nervous system. This is not an original thought because, as you well know, many other molecular biologists are thinking in the same way. The great difficulty about these fields is that the nature of the problem has not yet been clearly defined, and hence the right experimental approach is not known. There is a lot of talk about control mechanisms, and very little more than that.
It seems to me that, both in development and in the nervous system, one of the serious problems is our inability to define unitary steps of any given process. Molecular biology succeeded in its analysis of genetic mechanisms partly because geneticists had generated the idea of one gene-one enzyme, and the apparently complicated expressions of genes in terms of eye color, wing length and so on could be reduced to simple units which were capable of being analyzed. Molecular biology succeeded also because there were simple model systems such as phages which exhibited all the essential features of higher organisms so far as replication and expression of the genetic material were concerned, and which simplified the experimental work considerably. And, of course, there were the central ideas about DNA and protein structure.
In the study of development and the nervous system, there is nothing approaching these ideas at the present time. It is possible that the repressor/operator theory of Jacob and Monod will be the central clue, but there is not very much to suggest that this is so, at least in its simple form. There may well be insufficient information of the right kind to generate a central idea, and what we may require at the present is experimentation into these problems.
The experimental approach I would like to follow is to attempt to define the unitary steps of development using the techniques of genetic analysis. At present, we are producing and analyzing conditional lethal mutants of bacteria. These are mutants which are unable to grow at 44C but do grow normally at 37C. The mutations affect genes controlling the more sophisticated processes of the bacterial cell, and some work which we have already done indicates that it will be possible to dissect the process of cell division into its unitary steps. We have mutants in which neither a cell membrane septum nor a cell wall is made, others in which a septum is made but not a cell wall septum and so on. We have mutants in which the control of DNA replication is affected. I intend to expand this research activity in the near future.
Our success with bacteria has suggested to me that we could use the same approach to study the specification and control of more complex processes in cells of higher organisms. As a first stage, I would like to initiate studies into the control of cell division in higher cells, in particular to try to find out what determines meiosis and mitosis. In this work there is a great need to "microbiologize" the material so that one can handle the cells as one handles bacteria and viruses. Hence, like in the case of replication and transcription, one wants a model system. For cell division, in particular meiosis, the ciliates seem the likely candidates. Already, in these cells, the basic plan of meiosis is present and there is no doubt that the controlling elements must be the same in ciliates as they are in the oocytes of mammals.
Another possibility is to study the control of flagellation and ciliation. This again is a differentiation in higher cells and its control must resemble the control in amoebo-flagellates.
As a more long term possibility, I would like to tame a small metazoan organism to study development directly. My ideas on this are still fluid and I cannot specify this in greater detail at the present time.
As an even more long term project, I would like to explore the possibilities of studying the development of the nervous system using insects...
In summary, it is probably true to say that no major discovery comparable in importance to that of, say, messenger RNA, now lies ahead in this field, but the detailed elucidation of the mechanisms already discovered is nevertheless vital.
The new major problem in molecular biology is the genetics and biochemistry of control mechanisms in cellular development. We propose to start work in this field and gradually make it the Division's main research.
In the first place, control mechanisms can be studied most easily in micro-organisms, and this work has already begun. In addition we should like to start exploratory work on one of two model systems. We have in mind small metazoa, chosen because they would be suitable for rapid genetic and biochemical analysis. Proposals for such work, which we plan to begin within the next few months, are set out in Appendix I.
Part of the success of molecular genetics was due to the use of extremely simple organisms which could be handled in large numbers: bacteria and bacterial viruses. The processes of genetic replication and transcription, of genetic recombination and mutagenesis, and the synthesis of enzymes could be studied there in their most elementary form, and, having once been discovered, their applicability to the higher forms of life could be tested afterwards. We should like to attack the problem of cellular development in a similar fashion, choosing the simplest possible differentiated organism and subjecting it to the analytical methods of microbial genetics.
Thus we want a multicellular organism which has a short life cycle, can be easily cultivated, and is small enough to be handled in large numbers, like a micro-organism. It should have relatively few cells, so that exhaustive studies of lineage and patterns can be made, and should be amenable to genetic analysis.
We think we have a good candidate in the form of a small nematode worm, Caenorhabditis briggsae, which has the following properties. It is a self-fertilizing hermaphrodite, and sexual propagation is therefore independent of population size. Males are also found (0.1%), which can fertilize the hermaphrodites, allowing stocks to be constructed by genetic crosses. Each worm lays up to 200 eggs which hatch in buffer in twelve hours, producing larvae 80 microns in length. These larvae grow to a length of 1 mm in three and a half days, and reach sexual maturity. However, there is no increase in cell number, only in cell mass. The number of nuclei becomes constant at a late stage in development, and divisions occur only in the germ line. Although the total number of cells is only about a thousand, the organism is differentiated and has an epidermis, intestine, excretory system, nerve and muscle cells. Reports in the literature describe the approximate number of cells as follows: 200 cells in the gut, 200 epidermal cells, 60 muscle cells, 200 nerve cells. The organism normally feeds on bacteria, but can also be grown in large quantities in liver extract broth. It has not yet been grown in a defined synthetic medium.
To start with we propose to identify every cell in the worm and trace lineages. We shall also investigate the constancy of development and study its control by looking for mutants.
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