Deck 9: Bacterial and Viral Genetic Systems

In order to better understand arginine biosynthesis in bacteria, a microbial geneticist might first isolate mutant bacterial strains.
a. What characteristics must these mutant bacteria have?
b. Outline a strategy for isolating such mutants.
c. List three possible methods for mapping the genetic location of the mutations in these strains.

A bacterium of genotype a⁺b⁺c⁺d⁺ is the donor in a cotransformation mapping. The recipient is a^-b^-c^-d^-. Data from the transformed cells (genotype and percent of each cotransformant) are shown below. What is the order of the genes? $$\begin{array} { l c } \text { Genotype } & \text { Cotransformants } \\a ^ { + } \text {and } b ^ { + } & 2 \% \\a ^ { + } \text {and } c ^ { + } & 0 \% \\a ^ { + } \text {and } d ^ { + } & 5 \% \\b ^ { + } \text {and } c ^ { + } & 5 \% \\b ^ { + } \text {and } a ^ { + } & 0 \% \\c ^ { + } \text {and } d ^ { + } & 0 \%\end{array}$$

What are plasmids and what purposes do they serve?

In a transformation experiment in the bacterium Streptococcus, the donor has the genotype d⁺e⁺f⁺ (order is not known). The recipient strain is d^-e^-f^- and f⁺ transformants are selected for. The complete genotype is determined for each of the f⁺ transformants and the results are shown below. What is the cotransformation frequency between f and e? $\begin{array} { l c } Genotype&Number~ of ~transformants\\\\a ^ { + } e ^ { + } f ^ { + } & 25 \\ a ^ { + } e ^ { - f ^ { + } } & 4 \\ a ^ { - } e ^ { + } f ^ { + } & 80 \\ a ^ { - } e ^ { - } f ^ { + } & 256 \end{array}$

List and describe three different ways that DNA from one bacterium can be transferred into bacterial cells.

A transformation experiment is performed with a donor strain that is resistant to four drugs: A, B, C, and D determined by genes A, B, C, and D. The recipient strain is sensitive to all four drugs. The treated recipient-cell population is divided up and plated on media containing various combinations of the drugs. A cell that is resistant to the added drug(s) will form a colony. The table below shows the results. $$\begin{array} { l l l l } \text { Drug(s) Added } & \text { Number of Colonies } & \text { Drug(s) Added } & \text { Number of Colonies } \\\hline \text { None } & 10,000 & \mathrm { BC } & 51 \\\text { A } & 1,156 & \mathrm { BD } & 49 \\\text { B } & 1,148 & \mathrm { CD } & 786 \\\text { C } & 1,161 & \mathrm { ABC } & 30 \\\text { D } & 1,139 & \mathrm { ABD } & 42 \\\text { AB } & 46 & \mathrm { ACD } & 630 \\\text { AC } & 640 & \mathrm { BCD } & 36 \\\text { AD } & 942 & \text { ABCD } & 30\end{array}$$ One of the genes is quite distant from the other three that are tightly linked. Which gene is distant from the other three?

You are mapping five bacterial genes using cotransformation frequencies. The genes are designated A, B, C, D, and E. You perform a series of crosses and measure the percent cotransformation between all pairs of genes. The results are shown in the table below. Percent contransformation between gene pairs
$\begin{array} { l l l l l l } & A & B & C & D & E \\ A & - & & & & \\ B & 55 & - & & & \\ C & 14 & 32 & - & & \\ D & 80 & 65 & 22 & - & \\ E & 45 & 25 & 4 & 34 & - \end{array}$ What is the CORRECT order for the five genes?

Outline the steps involved in mapping a bacterial chromosome by conjugation.

What causes an F^- cell to be converted to F⁺?

What causes an F^- cell to be converted to Hfr in the presence of F⁺ cells?

(a) Explain how chromosomal genes are transferred from donors to recipients when cells of an F⁺ strain are mixed with F^- cells. (b) Explain why transfer of chromosomal genes occurs at a higher frequency when cells of an Hfr strain are mixed with F^- cells.

Explain the significance of horizontal gene transfer to bacterial evolution and to our ability to discern relationships between different groups of bacteria.

(a) What is an F´ plasmid and how is it formed? (b) Explain how an F´ can be used to construct a bacterial strain that is partially diploid. (c) Explain how partial diploid strains can be used to assess interactions between different alleles (e.g., lac ⁺ and lac^-).

A transformation experiment is performed with a donor strain that is resistant to four drugs, A, B, C, and D, determined by genes A, B, C, and D. The recipient strain is sensitive to all four drugs. The treated recipient-cell population is divided up and plated on media containing various combinations of the drugs. A cell that is resistant to the added drug(s) will form a colony. The table below shows the results. $$\begin{array} { l l l l } \text { Drug(s) Added } & \text { Number of Colonies } & \text { Drug(s) Added } & \text { Number of Colonies } \\\hline \text { None } & 10,000 & \mathrm { BC } & 51 \\\text { A } & 1,156 & \mathrm { BD } & 49 \\\text { B } & 1,148 & \mathrm { CD } & 786 \\\text { C } & 1,161 & \mathrm { ABC } & 30 \\\text { D } & 1,139 & \mathrm { ABD } & 42 \\\text { AB } & 46 & \mathrm { ACD } & 630 \\\text { AC } & 640 & \mathrm { BCD } & 36 \\\text { AD } & 942 & \text { ABCD } & 30\end{array}$$ One of the genes is quite distant from the other three that are tightly linked. What is the probable order of the three tightly linked genes?

You perform interrupted conjugation using an a⁺b⁺c⁺d⁺l⁺m⁺n⁺o⁺ Hfr strain and an F^- strain that is a^-b^-c^-d^-l^-m^-n^-o^-. You observe the following genes transferred together in order from last to first:
n⁺a⁺c⁺m⁺
o⁺m⁺c⁺a⁺n⁺
o⁺b⁺d⁺l⁺n⁺
What is the map order of the genes?

The table below shows the results of interrupted-mating experiments with three different Hfr strains. What is the order of the genes, starting with C? $$\begin{array} { | c c | } \hline \text { Hfr strain } & \text { Order of transfer } \\\hline 1 & A , B , E , D , F \\\hline 2 & D , F , C , G , A \\\hline 3 & D , E , B , A , G \\\hline\end{array}$$

Outline the steps involved in mapping a bacterial chromosome by cotransformation.

In E. coli, a P1 generalized transduction was carried out using a donor strain of ara⁺ leu⁺ ilvH⁺ genotype. The recipient strain was ara^- leu^- ilvH^-. 381 ara⁺ transductants were first recovered and then the remaining genotypes of these 381 were determined and the results are shown below: $$\begin{array} { l } \mathrm { ara } ^ { + } \text {leu}^-{ ilvH }^- \quad = 32 \\\mathrm { ara } ^ { + } \mathrm { leu } ^ { + } i \mathrm { lv } \mathrm { H } ^ { - } = 9 \\\mathrm { ara } ^ { + } \operatorname { leu }^- i \mathrm { lv } \mathrm { H } ^ { + } = 0 \\\mathrm { ara } ^ { + } \mathrm { leu } ^ { + } \mathrm { llv } \mathrm { H } ^ { + } \quad = 340 \\\end{array}$$ Which gene is in the middle?

A recipient gal^- bio^- attl^- strain of E. coli is transduced by P1 phage from a donor wild-type gal⁺ bio⁺ attl⁺ strain. (attl^- is a mutant which can't form a l prophage because the site for l integration is missing or defective.) gal⁺ transductants are selected for by plating the recipient cells on a Moderate with galactose as the sole carbon or energy source. Replica plating and testing for lysogenic ability give the complete genotypes of 106 transductants: Class 1: $\quad \mathrm { gal } ^ { + } \mathrm { bio } ^ { - } \mathrm { attl } ^ { - } \quad 71$
Class 2: $\quad \mathrm { gal } ^ { + } \mathrm { bio } ^ { + }attl^-$ $\quad 0$
Class 3: $\quad\mathrm { gal } ^ { + }bio^-$ $a t t l ^ { + } \quad 9$
Class 4: $\quad \mathrm { gal } ^ { + } \mathrm { bio } ^ { + } \mathrm { attl } ^ { + } \quad 26$ What is the frequency of cotransduction between gal and attl?

A mapping study was done with the E. coli genes cheA, cheB, eda, and supD using P1 generalized transduction. The frequency of cotransduction was determined for pairs of genes as shown below. $$\begin{array} { l c } \text { Markers } & \% \text { Cotransduction } \\\text { che A-eda } & 15 \\\text { cheA-supD } & 5 \\\text { cheB-eda } & 28 \\\text { cheB- } \sup D & 2.7 \\\text { eda-sup } & 0\end{array}$$ What is the MOST probable order for the four genes?

In E. coli, a P1 generalized transduction was carried out using a donor strain of ara⁺ leu⁺ ilvH⁺ genotype. The recipient strain was ara^- leu^- ilvH^-. 381 ara⁺ transductants were first recovered and then the remaining genotypes of these 381 were determined and the results are shown below: $$\begin{array} { l } \mathrm { ara } ^ { + } \text {leu}^-{ ilvH }^- \quad = 32 \\\mathrm { ara } ^ { + } \mathrm { leu } ^ { + } i \mathrm { lv } \mathrm { H } ^ { - } = 9 \\\mathrm { ara } ^ { + } \operatorname { leu }^- i \mathrm { lv } \mathrm { H } ^ { + } = 0 \\\mathrm { ara } ^ { + } \mathrm { leu } ^ { + } \mathrm { llv } \mathrm { H } ^ { + } \quad = 340 \\\end{array}$$ What is the cotransduction frequency between ara and leu?

Generalized transduction by phage P1 of four E. coli genes (a, b, c, and d) shows the following percentages of cotransduction: $$\begin{array} { l l l r } a - b & 51 \% & b - c & 2 \% \\b - d & 12 \% & a - d & 40 \% \\a - c & 19 \% & c - d & 79 \%\end{array}$$ What is the CORRECT order of the four genes?

Two mutations that affect plaque morphology in a particular phage (a^- and b^-) have been isolated. Phages carrying both mutations (a^-b^-) are mixed with wild-type phage (a⁺b⁺) and added to a culture of bacterial cells. Following infection and lysis, samples of the phage lysate are collected and cultured on bacterial cells. The following numbers of plaques are observed: $$\begin{array}{l}\begin{array} { l r } \text { Plaque Phenotype}&{ Number }\\a ^ { + } b ^ { + } & 2043 \\a ^ { + } b & 320 \\a ^ { - } b ^ { + } & 357 \\a^- b ^ { - } & 2134\end{array}\end{array}$$ What is the frequency of recombination between the a and b genes?

HIV has a high mutation rate. What causes this, and how might this be advantageous to the virus?

You are using phages to map three toxin-production genes (R, Y, and
G) in a new bacterium. You grow phages in a strain of the bacteria that produces all three toxins (R⁺, Y⁺, G⁺), isolate the phage, and then infect a second bacterial strain that cannot produce any of the toxins (R^-, Y^-, G^-). The recipient bacteria are then grown on colorimetric media (media that change color in response to toxin presence) to see which toxin genes are transferred together by the phage. The data are as follows:

a. What kind of mapping is this called?
b. Which gene is in the middle?
c. Which of the outside genes is closer to the middle gene?

Outline the steps involved in mapping bacterial genes by generalized transduction.

A retrovirus has an RNA genome but integrates into the DNA chromosome of a host cell. Explain how it does this.

What is the difference between specialized and generalized transduction?

Two phage phenotypes are controlled by the genes a and b. In a mapping experiment, a culture of bacteria is infected simultaneously with an a^-b⁺ strain and an a⁺b^- strain. When plaques are analyzed, five out of 1000 have the a⁺b⁺ or a^-b^- phenotype. Based on the information, how far apart are genes a and b?

You are studying a new phage that infects H. pylori. You have isolated two mutant strains of the phage, each producing a different plaque phenotype due to a specific mutation: rough (r) and big (b). You co-infect H. pylori with both strains by adding a mixture of phages to a culture of cells. You collect the cell lysate containing progeny phages, plate diluted phages on a lawn of H. pylori cells, and observe 970 rough plaques, 890 big plaques, 0 rough and big plaques, and 0 normal, wild-type plaques.
a. What is the recombination frequency between the r locus and the b locus?
b. How can you explain the results?

How does a virulent phage differ from a temperate phage?

A virulent bacteriophage is used to infect a prototrophic bacterial culture. Phages are collected from the culture and are used to infect a new bacterial strain that has several auxotrophies. After infection, rare prototrophs are found: How are the auxotrophy genes organized on the bacterial chromosome?

(a) Explain the mechanism that leads to rapid evolution of the virus that causes influenza. (b) Distinguish between antigenic drift and antigenic shift, and explain the significance of each to influenza evolution and the occurrence of influenza in humans.

Both retroviruses and lysogenic bacteriophages employ a mechanism that allows them to be replicated and passed from cell to cell without producing viruses. What is the common mechanism that these two very different viruses use?