We used whole-genome design and complete chemical synthesis to minimize the 1079-kilobase pair synthetic genome of Mycoplasma mycoides JCVI-syn1.0. An initial design, based on collective knowledge of molecular biology combined with limited transposon mutagenesis data, failed to produce a viable cell. Improved transposon mutagenesis methods revealed a class of quasi-essential genes that are needed for robust growth, explaining the failure of our initial design. Three cycles of design, synthesis, and testing, with retention of quasi-essential genes, produced JCVI-syn3.0 (531 kilobase pairs, 473 genes), which has a genome smaller than that of any autonomously replicating cell found in nature. JCVI-syn3.0 retains almost all genes involved in the synthesis and processing of macromolecules. Unexpectedly, it also contains 149 genes with unknown biological functions. JCVI-syn3.0 is a versatile platform for investigating the core functions of life and for exploring whole-genome design.
JCVI-syn3A, a robust minimal cell with a 543 kbp genome and 493 genes, provides a versatile platform to study the basics of life. Using the vast amount of experimental information available on its precursor, Mycoplasma mycoides capri, we assembled a near-complete metabolic network with 98% of enzymatic reactions supported by annotation or experiment. The model agrees well with genome-scale in vivo transposon mutagenesis experiments, showing a Matthews correlation coefficient of 0.59. The genes in the reconstruction have a high in vivo essentiality or quasi-essentiality of 92% (68% essential), compared to 79% in silico essentiality. This coherent model of the minimal metabolism in JCVI-syn3A at the same time also points toward specific open questions regarding the minimal genome of JCVI-syn3A, which still contains many genes of generic or completely unclear function. In particular, the model, its comparison to in vivo essentiality and proteomics data yield specific hypotheses on gene functions and metabolic capabilities; and provide suggestions for several further gene removals. In this way, the model and its accompanying data guide future investigations of the minimal cell. Finally, the identification of 30 essential genes with unclear function will motivate the search for new biological mechanisms beyond metabolism.
Antigenic diversity is generated in the wall‐less pathogen Mycoplasma hyorhinis by combinatorial expression and phase variation of multiple, size‐variant membrane surface lipoproteins (Vlps). The unusual structural basis for Vlp variation was revealed in a cluster of related but divergent vlp genes, vlpA, vlpB and vlpC, which occur as single chromosomal copies. These encode conserved N‐terminal domains for membrane insertion and lipoprotein processing, but divergent external domains undergoing size variation by loss or gain of repetitive intragenic coding sequences while retaining a motif with distinctive charge distribution. Genetic analysis of phenotypically switched isogenic lineages representing ON or OFF expression states of Vlp products ruled out chromosomal rearrangement or frameshift mutations as mechanisms for Vlp phase variation. However, highly conserved vlp promoter regions contain a tract of contiguous A residues immediately upstream of the −10 box which is subject to frequent mutations altering its length in exact correspondence with the ON and OFF phase states of specific genes. This suggests a mechanism of transcriptional control regulating high frequency phase variation and random combinatorial expression of Vlps. The multiple levels of diversity embodied in the vlp gene cluster represents a novel adaptive capability particularly suited for this class of wall‐less microbe.
The ability of some microorganisms to rapidly alter the expression and structure of surface components reflects an important strategy for adaptation to changing environments, including those encountered by infectious agents within respective host organisms. Mycoplasma hyorhinis, a wall-less prokaryotic pathogen of the class Mollicutes, is shown to undergo high-frequency phase transitions in colony morphology and opacity and in the expression of diverse lipid-modified, cell-surface protein antigens. These proteins spontaneously vary in size, contain highly repetitive structures, and are oriented with their carboxyl-terminal region external to the membrane. Thus, mycoplasma membrane lipoproteins generate microbial surface diversity and may be part of a complex system that controls interactions of these organisms with their hosts.
Isogenic populations of Mycoplasma hyorhinis undergo in vitro high-frequency phase variation in the expression of surface lipoproteins; these products also vary markedly in size through changes in periodic protein structure (R. Rosengarten and K.S. Wise, Science 247:315-318, 1990). In this report, we rigorously define three distinct translation products comprising the Vlp (variable lipoprotein) system of M. hyorhinis SK76 and establish parameters of Vlp structural diversity and expression that distinguish the Vlp system from previously described examples of antigenic variation. VlpA, VlpB, and VlpC are prominent amphiphilic membrane lipoproteins characterized by detergent-phase fractionation and metabolic labeling with [35S]cysteine and [3H]palmitate. VlpA is distinguished from VlpB and VlpC by its selective labeling with [35S]methionine; VlpB and VlpC are distinguished by specific epitopes defined by surface-binding monoclonal antibodies (MAbs); a third MAb defines a surface epitope shared by VlpB and VlpC (but absent from VlpA). Each Vlp displays 12 to 30 spontaneous size variant forms comprising a periodic ladder that could also be generated by partial trypsin digestion of individual Vlp size variants. Different periodic intervals within VlpB and VlpC further distinguish these two products structurally. Mycoplasma colony opacity correlates inversely with Vlp size. Each Vlp undergoes independent, oscillating high-frequency phase variation in isogenic populations and can be expressed individually or concomitantly with other Vlps in a noncoordinate manner. All seven possible combinations of these three products were observed; however, no variants were found that lacked a Vlp. High-frequency size variation of each Vlp superimposed on combinatorial diversity in Vlp expression yields greater than 10(4) possible structurally distinct Vlp mosaics, of which 104 were documented along with 24 of 42 possible transitions among the seven Vlp combinations. In addition to these features, VlpA, VlpB, and VlpC were specifically recognized by serum antibodies from swine with experimental M. hyorhinis SK76-induced arthritis, indicating expression and immunogenicity of Vlps in the natural host. The structure and variation of Vlps and their known involvement in MAb-mediated modulation of mycoplasma-infected host cell properties and mycoplasma killing are discussed in relation to the surface architecture and adaptive potential of the wall-less mycoplasmas.
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