haemolyticus, and that the proportions of licD III and licD IV alleles are similar between the species. ChoP phase variation
and the number of licA tetranucleotide (5′-CAAT-3′) repeats #Selleckchem EPZ-6438 randurls[1|1|,|CHEM1|]# among NT H. influenzae and H. haemolyticus Phase variation of ChoP expression is similar between NT H. influenzae and H. haemolyticus. The licA genes of H. haemolyticus strains M07-22 and 60P3H1 contained a number of 5′-CAAT-3′ repeats that would place the licA gene in a correct translational open reading frame (data not shown). ChoP expression in these two strains was corroborated by Western immunoblot where TEPC-15 reactive epitopes were present in each strain (Figure 1, lanes 4 and 5). In addition, phase-negative variants could be isolated from each H. haemolyticus strain, and DNA sequence analysis revealed that each licA repeat region gained one 5′-CAAT-3′ repeat, placing the licA gene out of frame (data not shown). Mutation rates in contingency loci are proportional to the length of the repeat region in the loci and the repeat region length may therefore affect the ability of bacteria to respond to a host immunologic
challenge [31]. To determine if a general population difference of licA repeat length exists between the species in this study, we compared the number of licA 5′-CAAT-3′ repeats between the 74 NT H. influenzae and 46 H. haemolyticus strains that contained a single lic1 locus. DNA sequence analysis of PCR amplified repeat regions from these strains revealed a wide range in repeat numbers for both species (5-45 and 6-56 repeats for NT H. influenzae and H. haemolyticus, respectively) selleckchem (Figure 3, Table 3). The average number of licA repeats between the species, however, was statistically different with NT H. influenzae
having a mean of 27 repeats Regorafenib datasheet and H. haemolyticus having a mean of 15 repeats (P < .0001 using the student’s T test) (Table 3). These results suggest that, at the population level, the contingency response for ChoP expression may be slower for H. haemolyticus than for NT H. influenzae. Figure 3 Distribution of NT H. influenzae and H. haemolyticus strains with various numbers of CAAT repeats. Percent of lic1-positive NT H. influenzae and H. haemolyticus strains based on the number of CAAT repeats they contain. NT H. influenzae and H. haemolyticus are labeled in blue and red, respectively. Table 3 Stratification of the number of licA gene 5′-CAAT-3′ repeats between species and licD alleles Stratification Strains (n) Range Average ± S.D. Species NT H. influenzae 74 5-45 27 ± 10* H. haemolyticus 46 6-56 15 ± 4 NT H. influenzae licD alleles licD I 40 6-45 25 ± 9 licD III 14 5-43 34 ± 11** licD IV 20 9-42 26 ± 8 H. haemolyticus licD alleles licD III 23 6-56 16 ± 13 licD IV 23 6-27 13 ± 6 * P < .0001 using the student’s T-test ** P < .05 for each comparison using the student’s T-test H. influenzae strains that express ChoP at more distal positions in LOS (i.e.