Pyrimidine Auxotrophs Research Articles

Development of Saccharomyces cerevisiae as a model pathogen. A system for the genetic identification of gene products required for survival in the mammalian host environment.

Saccharomyces cerevisiae, a close relative of the pathogenic Candida species, is an emerging opportunistic pathogen. An isogenic series of S. cerevisiae strains, derived from a human clinical isolate, were used to examine the role of evolutionarily conserved pathways in fungal survival in a mouse host. As is the case for the corresponding Candida albicans and Cryptococcus neoformans mutants, S. cerevisiae purine and pyrimidine auxotrophs were severely deficient in survival, consistent with there being evolutionary conservation of survival traits. Resistance to the antifungal drug 5-fluorocytosine was not deleterious and appeared to be slightly advantageous in vivo. Of mutants in three amino acid biosynthetic pathways, only leu2 mutants were severely deficient in vivo. Unlike the glyoxylate cycle, respiration was very important for survival; however, the mitochondrial genome made a respiration-independent contribution to survival. Mutants deficient in pseudohyphal formation were tested in vivo; flo11Delta mutants were phenotypically neutral while flo8Delta, tec1Delta, and flo8Delta tec1Delta mutants were slightly deficient. Because of its ease of genetic manipulation and the immense S. cerevisiae database, which includes the best annotated eukaryotic genome sequence, S. cerevisiae is a superb model system for the identification of gene products important for fungal survival in the mammalian host environment.

A food-grade cloning system for industrial strains of Lactococcus lactis.

We have previously reported the construction of a food-grade cloning vector for Lactococcus using the ochre suppressor, supB, as the selective marker. This vector, pFG1, causes only a slight growth inhibition in the laboratory strain MG1363 but is unstable in the industrial strains tested. As supB suppresses both amber and ochre stop codons, which are present in 82% of all known lactococcal genes, this undesirable finding may result from the accumulation of elongated mistranslated polypeptides. Here, we report the development of a new food-grade cloning vector, pFG200, which is suitable for overexpressing a variety of genes in industrial strains of Lactococcus lactis. The vector uses an amber suppressor, supD, as selectable marker and consists entirely of Lactococcus DNA, with the exception of a small polylinker region. Using suppressible pyrimidine auxotrophs, selection and maintenance are efficient in any pyrimidine-free medium including milk. Importantly, the presence of this vector in a variety of industrial strains has no significant effect on the growth rate or the rate of acidification in milk, making this an ideal system for food-grade modification of industrially relevant L. lactis strains. The usefulness of this system is demonstrated by overexpressing the pepN gene in a number of industrial backgrounds.

Isolation and characterization of pyrimidine auxotrophs, and molecular cloning of the pyrE gene from the hyperthermophilic archaeon Pyrococcus abyssi.

Uracil auxotrophic mutants of the hyperthermophilic archaeon Pyrococcus abyssi were isolated by screening for resistance to 5-fluoro-orotic acid (5-FOA). Wild-type strains were unable to grow on medium containing 5-FOA, whereas mutants grew normally. Enzymatic assays of extracts from wild-type P. abyssi and from pyrimidine auxotrophs demonstrated that the mutants are deficient in orotate phosphoribosyltransferase (PyrE) and/or orotidine-5'-monophosphate decarboxylase (PyrF) activity. The pyrE gene of wild-type P. abyssi and one of its mutant derivatives were cloned and sequenced. This pyrE gene could serve as selectable marker for the development of gene manipulation systems in archaeal hyperthermophiles.

Generation and testing of mutants of Enterococcus faecalis in a mouse peritonitis model.

A previously described mouse peritonitis model was used to study derivatives of Enterococcus faecalis strain OG1RF. The addition of sterile rat fecal extracts (SRFE) lowered the LD50 of OG1RF >10-fold. Hemolysin production caused a 35-fold lower LD50 and a much shorter survival, similar to previous results using a peritonitis model without SRFE. A purine (but not a pyrimidine) auxotroph was considerably less lethal than wild type; gelatinase mutants were also attenuated. A suicide vector was generated with an enterococcal selectable marker in order to disrupt a gene encoding an E. faecalis antigen; the resulting mutant was not attenuated despite a slower growth rate. In conclusion, this model allows attenuated mutants to be detected, corroborates prior reports that hemolysin is a virulence factor, and suggests a role for gelatinase in virulence of E. faecalis in mice; the attenuated purine auxotroph may provide a system for developing vectors for in vivo expression systems.

Chromosomal marker exchange in the thermophilic archaeon Sulfolobus acidocaldarius: physiological and cellular aspects.

Exchange and recombination of chromosomal markers is an intrinsic genetic property of the thermoacidophilic archaeon Sulfolobus acidocaldarius that has not been thoroughly characterized. To clarify the mechanism and experimental usefulness of this process, the frequency of S. acidocaldarius prototrophs produced from mixtures of two pyrimidine auxotrophs under a variety of conditions was determined. The apparent efficiency of genetic exchange was essentially independent of the density of cells deposited on the surface of solid media. Furthermore, recombinant formation could initiate in liquid suspensions, as indicated by high recombinant frequencies resulting from mixtures plated at low cell densities, and the formation of recombinants at equal or higher frequencies in liquid suspensions that were never plated. Apparent initiation of genetic exchange in liquid at 22 °C was not prevented by DNase, prior digestion of parental cells with protease from Streptomyces griseus, or any other non-lethal chemical agent tested. The results support prior indications that chromosomal marker exchange in S. acidocaldarius proceeds via conjugation, and further indicate that this conjugation can initiate quickly in dilute liquid suspension. The mating system of S. acidocaldarius thus appears physiologically distinct from that of Haloferax volcanii but perhaps similar to conjugational transfer of Sulfolobus plasmid pNOB8. The frequency of recombinants formed in these assays (10-4-10-5 per c.f.u.) greatly exceeds the number of spontaneous forward mutational events per generation for biosynthetic genes in S. acidocaldarius. This suggests that chromosomal exchange has the potential to influence the genetic dynamics of natural Sulfolobus populations.

Isolation, characterization and transformation, by autonomous replication, of Mucor circinelloides OMPdecase-deficient mutants.

Pyrimidine auxotrophs of Mucor circinelloides were isolated after mutagenesis with nitrosoguanidine and selected for resistance to 5-fluoroorotate. These mutants were genetically and biochemically characterized and found to be deficient either in orotidine-5'-monophosphate decarboxylase (OMPdecase) activity or in orotate phosphoribosyl transferase (OPRTase) activity. Different circular DNA molecules containing the homologous pyrG gene were used to transform a representative OMPdecase-deficient strain to uracil prototrophy. Southern analysis, as well as mitotic stability analysis of the transformants, showed that the transforming DNA is always maintained extrachromosomally. The smallest fragment tested that retained both the capacity to complement the pyrG4 mutation and the ability to be maintained extrachromosomally when cloned in a suitable vector is a 1.85 kb M. circinelloides genomic DNA fragment. This fragment consists of the pyrG coding region flanked by 606 nucleotides at the 5' and 330 nucleotides at the 3' ends, respectively. Sequence analysis reveals that it does not share any element in common with another M. circinelloides genomic DNA fragment which also promotes autonomous replication in this organism, except those related to transcription. Furthermore, it differs from elements which have been shown to be involved in autonomous replication in other fungal systems. An equivalent plasmid harbouring the heterologous Phycomyces blakesleeanus pyrG gene yielded lower transformation rates, but the transforming DNA was also maintained extrachromosomally. Our results suggest that autonomous replication in M. circinelloides may be driven by elements normally present in nuclear coding genes.

Selection and characterization of 5-fluoroorotate-resistant Plasmodium falciparum

Previous studies have shown that 100 nM 5-fluoroorotate (5-FO) is sufficient to block the in vitro proliferation of Plasmodium falciparum without causing toxicity to mammalian cells. In anticipation of potential drug resistance, a study was undertaken to identify P. falciparum cells that would proliferate in the presence of 5-FO. About 3 x 10(6) UV-irradiated as well as nonirradiated parasites were subjected to a one-step selection with 100 nM 5-FO both in the absence and in the presence of preformed pyrimidines (uracil, uridine, thymine, and thymidine). The P. falciparum cells that emerged after 3 weeks were cloned, and the 90% inhibitory concentration of 5-FO for the cloned cells was found to be 100- to 400-fold greater than that for the parent cell line. Two clones that were further characterized retained resistance to 5-FO even after prolonged propagation in culture without drug pressure. Since the mutants were not cross-resistant to 5-fluorouracil or to dihydrofolate reductase inhibitors, it was unlikely that alteration of thymidylate synthase or overproduction of the bifunctional dihydrofolate reductase-thymidylate synthase was responsible for 5-FO resistance. Similarly, resistance was not due to the expression of a pyrimidine salvage pathway since the cells were not pyrimidine auxotrophs, they did not show increased utilization of pyrimidine nucleosides, and they did not show increased susceptibility to 5-fluoropyrimidine nucleosides. When the selection experiments were repeated, without mutagenesis, in the presence of 10(-7) M 5-FO with fewer than 10(6) parasites or in the presence of more than 10(-7) M 5-FO with more than 10(8) parasites, viable mutants could not be recovered from the cultures. The implications of these findings for the in vivo use of 5-FO for malaria chemotherapy are discussed.

Isolation, characterization and mapping of pyrimidine auxotrophs of Phycomyces blakesleeanus.

A total of seven pyrimidine auxotrophs of Phycomyces were isolated from among 5-fluoroorotate acid (5-FOA)-resistant mutants. They were classified by complementation into two groups. A representative mutant strain belonging to one group was deficient in orotate phosphoribosyl transferase (OPRTase; EC 2.4.2.10) activity; the mutant strain belonging to the second group was deficient in orotidine-5'-monophosphate decarboxylase (OMPdecase; EC 4.1.1.23). These mutants are defective in the genes pyrF and pyrG respectively. The results from random spore analysis, tetrad analysis, and gene-centromere distances showed that these two markers are located in linkage group VI, with pyrG being a proximal marker and pyrF a distal one.

Sulfolobus acidocaldarius synthesizes UMP via a standard de novo pathway: results of biochemical-genetic study.

A genetic approach was used to establish the route of UMP biosynthesis in Sulfolobus acidocaldarius, a member of the hyperthermophilic division (the Crenarchaeota) of the Archaea domain. Pyrimidine auxotrophs of S. acidocaldarius DG6 were isolated by direct selection and by brute-force methods. Enzymatic assay of extracts from wild-type S. acidocaldarius, from pyrimidine auxotrophs, and from phenotypic revertants demonstrated that S. acidocaldarius synthesizes UMP via orotate in six enzymatic steps corresponding to the de novo pathway of other organisms. The results also show that a single carbamoyl phosphate synthetase supplies both the pyrimidine and arginine pathways of this organism. To gain similar insight into pyrimidine salvage pathway(s), prototrophic mutants resistant to toxic pyrimidine analogs were also isolated and characterized. The results suggest that a single class of mutants which had acquired elevated resistance to four different 5-fluoropyrimidines had been isolated. These fluoropyrimidine-resistant mutants appear to have a regulatory defect leading to overproduction of one or more endogenous pyrimidine compounds.

Role of a carboxyl-terminal helix in the assembly, interchain interactions, and stability of aspartate transcarbamoylase.

The six individual catalytic polypeptide chains within the two catalytic trimers of Escherichia coli aspartate transcarbamoylase (ATCase; EC 2.1.3.2) are folded into two discrete structural domains interconnected in part by helix 12, which comprises residues 285-305 and is located near the carboxyl terminus of the chain. The essential role of this helix in folding of the chains and their assembly into ATCase was demonstrated by introducing a stop codon at the position corresponding to amino acid 284, 291, or 299. Cells containing these mutations are pyrimidine auxotrophs lacking ATCase-like protein in cell extracts. In contrast, stable active enzyme is formed from chains truncated at position 306 or 307, showing that all 310 amino acids are not required for assembly. Replacements of Gln-288, Asn-291, Arg-296, and Ala-298 were introduced to assess the effect of alterations within helix 12 on protein stability. Stability of the trimers was measured both by differential scanning microcalorimetry and by the rate of exchange of chains at 4 degrees C when mutant trimers were incubated with succinylated wild-type trimers. Melting temperatures of the mutant trimers spanned a range of more than 20 degrees C, with a few higher and others lower than that of wild-type trimers. Large changes in interchain interaction energies were observed for the trimers, but there was no direct correlation between the ease of dissociation of the trimers and their thermal stability. Calorimetry on the mutant holoenzymes revealed alterations in the interactions between trimers and regulatory subunits within the intact enzymes. The striking changes in stability of both trimers and holoenzymes demonstrated that effects of relatively localized amino acid replacements in helix 12 are manifested by indirect global alterations propagated throughout the structure.

Tranformation of Neurospora pyr-4 with defective donor genes

Using the Vollmer/Orbach transformation protocol, transformation frequencies of a pyr-4 (OMP decarboxylase) strain of Neurospora crassa of circa 10(3)/µg are routinely achievable. At these levels of transformation, it is feasible to screen out ectopic integrations and look specifically for homologous integration events. Homologous integrants were sought by transforming a pyr-4 recipient with interrupted or incomplete copies of the cloned pyr-4 gene derived from the pyr+ clone in plasmid pFB6, selecting by complementation of the pyrimidine auxotrophy in the recipient

Cloning of the PYR3 gene of Ustilago maydis and its use in DNA transformation.

The Ustilago maydis PYR3 gene encoding dihydroorotase activity was cloned by direct complementation of Escherichia coli pyrC mutations. PYR3 transformants of E. coli pyrC mutants expressed homologous transcripts of a variety of sizes and regained dihydroorotase activity. PYR3 also complemented Saccharomyces cerevisiae ura4 mutations, and again multiple transcripts were expressed in transformants, and enzyme activity was regained. A 1.25-kilobase poly(rA)+ PYR3 transcript was detected in U. maydis itself. Linear DNA carrying the PYR3 gene transformed a U. maydis pyr3-1 pyrimidine auxotroph to prototrophy. Hybridization analysis revealed that three different types of transformants could be generated, depending on the structure of the transforming DNA used. The first type involved exchange of chromosomal mutant gene sequences with the cloned wild-type plasmid sequences. A second type had integrated linear transforming DNA at the chromosomal PYR3 locus, probably via a single crossover event. The third type had integrated transforming DNA sequences at multiple sites in the U. maydis genome. In the last two types, tandemly reiterated copies of the transforming DNA were found to have been integrated. All three types had lost the sensitivity of the parental pyr3-1 mutant to UV irradiation. They had also regained dihydroorotase activity, although its level did not correlate with the PYR3 gene copy number.

Cloning of the PYR3 gene of Ustilago maydis and its use in DNA transformation.

The Ustilago maydis PYR3 gene encoding dihydroorotase activity was cloned by direct complementation of Escherichia coli pyrC mutations. PYR3 transformants of E. coli pyrC mutants expressed homologous transcripts of a variety of sizes and regained dihydroorotase activity. PYR3 also complemented Saccharomyces cerevisiae ura4 mutations, and again multiple transcripts were expressed in transformants, and enzyme activity was regained. A 1.25-kilobase poly(rA)+ PYR3 transcript was detected in U. maydis itself. Linear DNA carrying the PYR3 gene transformed a U. maydis pyr3-1 pyrimidine auxotroph to prototrophy. Hybridization analysis revealed that three different types of transformants could be generated, depending on the structure of the transforming DNA used. The first type involved exchange of chromosomal mutant gene sequences with the cloned wild-type plasmid sequences. A second type had integrated linear transforming DNA at the chromosomal PYR3 locus, probably via a single crossover event. The third type had integrated transforming DNA sequences at multiple sites in the U. maydis genome. In the last two types, tandemly reiterated copies of the transforming DNA were found to have been integrated. All three types had lost the sensitivity of the parental pyr3-1 mutant to UV irradiation. They had also regained dihydroorotase activity, although its level did not correlate with the PYR3 gene copy number.

Rhizobial purine and pyrimidine auxotrophs: nutrient supplementation, genetic analysis, and the symbiotic requirement for the novo purine biosynthesis

Previously described Rhizobium leguminosarum bv. phaseoli mutants elicit nodules on bean without infection thread formation. These mutants were shown to be purine or, in one case, pyrimidine auxotrophs. Each of the seven purine auxotrophs grew normally when supplied the penultimate precursor of inosine, 5-aminoimidazole-4-carboxamide riboside. Four seemed blocked early in the purine pathway, because they were also thiamine auxotrophs. Reversion analysis and genetic complementation using cloned wild-type DNA showed that in each mutant a single mutation was responsible for both the symbiotic defect and purine or pyrimidine auxotrophy. The mutations were mapped to five dispersed chromosomal locations. The previously reported weak Calcofluor staining of these mutants on minimal agar appeared to be caused by partial growth on contaminating nutrients in the agar, rather than deficient exopolysaccharide production. Nodulation by the mutants was not enhanced by supplying purine or pyrimidine compounds exogenously. Furthermore, with or without added purine, the purine auxotrophs grew in the root environment as well as the wild type. However, nodulation by the purine auxotrophs was enhanced greatly in the presence of 5-aminoimidazole-4-carboxamide riboside. The results suggest that undiminished metabolic flow through de novo purine biosynthesis, or a particular intermediate in the pathway, is essential in early symbiotic interactions.

Selection and characterization of pyrG mutants of Penicillium chrysogenum lacking orotidine-5?-phosphate decarboxylase and complementation by the pyr4 gene of Neurospora crassaa

Pyrimidine auxotrophs of Penicillium chrysogenum have been isolated at a high frequency among mutants resistant to 5-fluoroorotic acid (5.2 mM). Some of the pyrimidine auxotrophs (e.g. strain pyrG1) showed no reversion. A radiometric assay based on the conversion of (6-14C)orotidine 5′-monophosphate (OMP) into (6-14C)uridine 5′-monophosphate (UMP) was developed to determine OMP-decarboxylase activity. One of the pyrimidine auxotrophs (P. chrysogenum pyrGl) was studied in detail. It was deficient in OMP-decarboxylase activity, whereas the parental strain (P. chrysogenum Wis. 54-1255) showed a normal enzyme activity. A five-fold higher OMP-decarboxylase activity was found in a P. chrysogenum pyrGI clone transformed with plasmids containing the Neurospora crassa pyr4 gene (which codes for the same enzyme).

The mapping of chromosomes in Saccharomyces cerevisiae: I. A cosmid vector designed to establish, by cloning into cdc-mutants, numerous start loci for chromosome walking in the yeast genome

A series of vectors for cosmid cloning in yeast has been derived from cosmid pHC79. Vectors pMT4 through pMT6 contain two tandemly arranged cohesive end sites ( cos) from the genome of bacteriophage γ Their design allows the rapid and simple preparation of cosmid arms by linearizing a vector at the unique PvwII-restriction site located between the two cos-sequences and then cutting the linearized molecule at one of its unique cloning sites for BamHI, ClaI, PvuI, SalI or Scal. Cosmids generated with arms from the most advanced vector, pMT6, carry the origin of replication ( ori) and the Ap R gene from pBR322 and the TRP1/ARS1 and URA1 genes from Saccharomyces cerevisiae. A yeast genomic DNA library was established by packaging in vitro, into bacteriophage λ preheads, of partially restricted yeast DNA fragments ligated to cosmid arms of vector pMT6. About 80% of the clones thus obtained comprise inserts of contiguous genomic DNA over 30 kb in length. Unique DNA probes for the yeast genes CDC10, CDC39, HIS4, LEU2, and PGK1 have successfully been applied when testing for completeness of this library by isolating a series of overlapping cosmid clones that carry the respective genes. The library will thus be useful for the selection of cosmid clones which carry CDC genes from yeast by complementing first, with the vectorial yeast gene URA1, the pyrimidine auxotrophy of most cdc-strains and then, with the respective CDC wild-type genes, of the temperature-sensitive mutant alleles. Most CDC clones thus obtained will provide unique DNA probes which serve as randomly distributed start sequences within the yeast genome for overlap hybridization screening in chromosome mapping studies.

Superproduction and rapid purification of Escherichia coli aspartate transcarbamylase and its catalytic subunit under extreme derepression of the pyrimidine pathway.

A strain of Escherichia coli has been constructed which greatly overproduces the enzyme aspartate transcarbamylase. This strain has a deletion in the pyrB region of the chromosome and also carries a leaky mutation in pyrF. Although this strain is a pyrimidine auxotroph, it will grow very slowly without pyrimidines if a plasmid containing the pyrB gene is introduced into it. Derepression occurs when this strain exhausts its uracil supply during exponential growth. Under extreme derepression, aspartate transcarbamylase can account for as much as 60% of the total cellular protein. This host strain/plasmid system can be utilized for the rapid purification of wild-type aspartate transcarbamylase or plasmid-born mutant versions of the enzyme. This system is particularly well-suited for analysis of the latter since the control of overproduction resides exclusively on the bacterial chromosome. Therefore, any plasmid bearing the pyrBI operon can be made to overproduce aspartate transcarbamylase in this host strain. Based on this system, a rapid purification procedure has been developed for E. coli aspartate transcarbamylase. The purification scheme involves an ammonium sulfate fractionation followed by a single precipitation of the enzyme at its isoelectric point. In a similar fashion, this strain can also be employed to produce exclusively the catalytic subunit of the enzyme if the plasmid only carries the pyrB gene. This system may be adapted to overproduce other proteins as well by using this host strain and the strong pyrB promoter linked to another gene.

Toxicity of the pyrimidine biosynthetic pathway intermediate carbamyl aspartate in Salmonella typhimurium.

Growth of Salmonella typhimurium pyrC or pyrD auxotrophs was severely inhibited in media that caused derepressed pyr gene expression. No such inhibition was observed with derepressed pyrA and pyrB auxotrophs. Growth inhibition was not due to the depletion of essential pyrimidine biosynthetic pathway intermediates or substrates. This result and the pattern of inhibition indicated that the accumulation of the pyrimidine biosynthetic pathway intermediate carbamyl aspartate was toxic. This intermediate is synthesized by the sequential action of the first two enzymes of the pathway encoded by pyrA and pyrB and is a substrate for the pyrC gene product. It should accumulate to high levels in pyrC or pyrD mutants when expression of the pyrA and pyrB genes is elevated. The introduction of either a pyrA or pyrB mutation into a pyrC strain eliminated the observed growth inhibition. Additionally, a direct correlation was shown between the severity of growth inhibition of a pyrC auxotroph and the levels of the enzymes that synthesize carbamyl aspartate. The mechanism of carbamyl aspartate toxicity was not identified, but many potential sites of growth inhibition were excluded. Carbamyl aspartate toxicity was shown to be useful as a phenotypic trait for classifying pyrimidine auxotrophs and may also be useful for positive selection of pyrA or pyrB mutants. Finally, we discuss ways of overcoming growth inhibition of pyrC and pyrD mutants under derepressing conditions.

Aspects of DNA repair and nucleotide pool imbalance.

Evidence that optimum repair depends on adequate pools of deoxynucleotide triphosphates (dNTPs) comes from the study of pyrimidine auxotrophs of Ustilago maydis. These strains are sensitive to UV light and X-rays, and for pyr1-1 it has been shown that the intracellular concentration of dTTP is reduced about 7-fold. Evidence has been published that DNA repair synthesis may require higher concentrations of dNTPs, than chromosome replication. The survival curve of pyr1-1 after UV-treatment, and split dose experiments with wild-type cells, provide evidence for an inducible repair mechanism, which probably depends on genetic recombination. Although inducible repair saves cellular resources, it has the disadvantage of becoming ineffective at doses which are high enough to inactivate the repressed structural gene(s) for repair enzymes. To ensure survival it is vital for organisms to preserve the integrity of their DNA, and this is accomplished both by accurate replication and by repair. It is clear that a wide variety of repair mechanisms have evolved to remove lesions which arise either spontaneously (such as the deamination of cytosine to uracil) or as a result of damage from external agents. Nevertheless, it would be incorrect to assume that all species require all possible pathways of repair. It is now well established that the accuracy of DNA and protein synthesis depends on proof-reading or editing mechanisms (for a review, see Ref. 5). These consume energy and may slow down the rate of synthesis, therefore organisms must invest metabolic resources to achieve any given level of accuracy. Optimum accuracy levels will evolve from the balance between error avoidance in macromolecular synthesis and physiological efficiency in growth and propagation [11, 12, 22].(ABSTRACT TRUNCATED AT 250 WORDS)

On auxotrophy for pyrimidines of respiration‐deficient chick embryo cells

Chick embryo cells treated with chloramphenicol are inherently resistant to the growth-inhibitory effect of the drug when cultured in the presence of tryptose phosphate broth. The cells were found to be auxotrophic for pyrimidines and the presence in the broth of compounds of pyrimidine origin is demonstrated by chromatographic procedures and mass spectral analyses. They are in the form of ribonucleosides, ribonucleotides and pyrimidine-containing oligoribonucleotides. To understand the mechanism responsible for pyrimidine auxotrophy, the activity of enzymes involved in the pyrimidine biosynthetic pathway was determined. Measurement of the conversion of dihydroorotic acid to orotic acid in cell-free extracts revealed that chloramphenicol-treated chick embryo cells are deficient in dihydroorotate dehydrogenase activity. The data in vitro are supported by studies on the nutritional requirements of the respiration-deficient cells and by the incorporation in vivo of labelled dihydroorotic acid into the acid-insoluble fraction of the cells. Although the activity of the dehydrogenase in vitro is decreased by 95%, the enzyme is present in chloramphenicol-treated cells and its activity is unmasked by the artificial electron acceptor menadione. A study of the activity of other enzymes of the pyrimidine biosynthetic pathway demonstrated that their activity is comparable to that in control cells. The present results indicate that auxotrophy for pyrimidines results from the inhibition of the flow of electrons along the mitochondrial electron transport chain.