Molecular analysis of isolates from influenza B outbreaks in the U.S. and Nepal, 2005.

Currently circulating influenza B viruses can be divided into two antigenically and genetically distinct lineages referred to by their respective prototype strains, B/Yamagata/16/88 and B/Victoria/2/87, based on amino acid differences in the hemagglutinin surface glycoprotein. During May and July 2005, clinical specimens from two early season influenza B outbreaks in Arizona and southeastern Nepal were subjected to antigenic (hemagglutinin inhibition) and nucleotide sequence analysis of hemagglutinin (HA1), neuraminidase (NA), and NB genes. All isolates exhibited little reactivity with the B/Shanghai/361/2002 (B/Yamagata-like) vaccine strain and significantly reduced reactivity with the previous 2003/04 B/Hong Kong/330/2001 (B/Victoria-like) vaccine strain. The majority of isolates were antigenically similar to B/Hawaii/33/2004, a B/Victoria-like reference strain. Sequence analysis indicated that 33 of 34 isolates contained B/Victoria-like HA and B/Yamagata-like NA and NB proteins. Thus, these outbreak isolates are both antigenically and genetically distinct from the current Northern Hemisphere vaccine virus strain as well as the previous 2003-04 B/Hong Kong/330/2001 (B/Victoria lineage) vaccine virus strain but are genetically similar to B/Malaysia/2506/2004, the vaccine strain proposed for the coming seasons in the Northern and Southern Hemispheres. Since these influenza B outbreaks occurred in two very distant geographical locations, these viruses may continue to circulate during the 2006 season, underscoring the importance of rapid molecular monitoring of HA, NA and NB for drift and reassortment.

Rapid extraction from and direct identification in clinical samples of methicillin-resistant staphylococci using the PCR.

Methicillin-resistant staphylococci (MRS) are one of the most common causes of nosocomial infections and bacteremia. Standard bacterial identification and susceptibility testing frequently require as long as 72 h to report results, and there may be difficulty in rapidly and accurately identifying methicillin resistance. The use of the PCR is a rapid and simple process for the amplification of target DNA sequences, which can be used to identify and test bacteria for antimicrobial resistance. However, many sample preparation methods are unsuitable for PCR utilization in the clinical laboratory because they either are not cost-effective, take too long to perform, or do not provide a satisfactory DNA template for PCR. Our goal was to provide same-day results to facilitate rapid diagnosis and therapy. In this report, we describe a rapid method for extraction of bacterial DNA directly from blood culture bottles that gave quality DNA for PCR in as little as 20 min. We compared this extraction method to the standard QIAGEN method for turnaround time (TAT), cost, purity, and use of template in PCR. Specific identification of MRS was determined using intragenic primer sets for bacterial and Staphylococcus 16S rRNA and mecA gene sequences. The PCR primer sets were validated with 416 isolates of staphylococci, including methicillin-resistant Staphylococcus aureus (n = 106), methicillin-sensitive S. aureus (n = 134), and coagulase-negative Staphylococcus (n = 176). The total supply cost of our extraction method and PCR was $2.15 per sample with a result TAT of less than 4 h. The methods described herein represent a rapid and accurate DNA extraction and PCR-based identification system, which makes the system an ideal candidate for use under austere field conditions and one that may have utility in the clinical laboratory.

Feasibility determination for use of polymerase chain reaction in the U.S. Air Force air-transportable hospital field environment: lessons learned.

At present, the use of molecular probes and polymerase chain reaction (PCR) for the identification of microorganisms in body fluids or tissues is becoming more commonplace. There is an added advantage when serological or culture methods are difficult, expensive, or unavailable. Slow-growing or fastidious microorganisms, including Mycobacterium tuberculosis, spirochetes, viruses, and the dimorphic fungi, can be detected rapidly using these techniques. The presence of different chromosomal or plasmid-mediated antibiotic-resistant markers can also be determined. PCR is an extremely powerful tool that has been applied to research, and more recently it has been used to augment standard clinical applications. It is a very simple process that can amplify nucleic acid sequences, both DNA and RNA, a million times over. The sensitivity, rapidity, broad applicability, and compactness of this technology make it an ideal candidate for use in the military arena. We recently established a molecular biology laboratory at a Deployable Medical System at the Camp Parks Army Reserve Training Facility in Dublin, California. This article will briefly summarize the use of PCR and its applicability in the air-transportable hospital field environment. Proper handling, processing, and testing as well as the requirements for setting up a molecular biology laboratory will be discussed. Finally, the benefits and disadvantages of using PCR-based techniques in the deployed field environment will be considered.

Cloning of insertion sequence IS1485 from Enterococcus species.

We have cloned and identified an insertion sequence, IS1485, that was present in several members of the genus Enterococcus. IS1485 exists in varying copy numbers with at least 12 copies in E. durans (ATCC 11576), 3 copies in E. faecium (ATCC 19434), and one copy each in E. faecalis (ATCC 19433) and E. avium (ATCC 14024). It was also detected in clinical strains of E. gallinarum, E. casseliflavus, and E. saccharolyticus. IS1485 is 1366 bp in length, it has imperfect terminal inverted repeats with 25 of the terminal 39 residues matched, and it contains three open reading frames exceeding 50 codons, designated orfA, orfB, and orfC. The largest, orfB, was located 36 bp downstream and in the -1 reading frame relative to orfA; orfC is oriented in the opposite direction and overlaps orfA. The genetic organization of IS1485 resembles that of members of the IS3 family of transposable elements. Sequence homology exists with several members of the IS3 family especially with IS199 from Streptococcus mutans.

Polymerase chain reaction: a link to the future.

Polymerase chain reaction (PCR) is a multi-faceted technology that is advancing disease detection. For pathology and clinical laboratories, PCR will be the tool of choice into the next century as scientists continue to develop and refine new uses. An amazingly simple process that amplifies nucleic acid sequences, PCR will change the practice of medicine because it will play a role in all aspects of the patient care continuum from diagnosis to treatment monitoring. Some striking applications range from detecting infectious and inherited diseases to assessing pharmacologic interventions. Additionally, the remarkable sensitivity of PCR will allow determination of a patient's genetic predisposition to diseases, thereby improving prevention modalities. Thus, medical practitioners should gain a basic understanding of this phenomenal cornerstone of molecular diagnostics. This article briefly reviews the history, theory, and uses of PCR and discusses relevant applications for military medicine.

Role of mecA transcriptional regulation in the phenotypic expression of methicillin resistance in Staphylococcus aureus.

The gene required for methicillin resistance in staphylococci, mecA, encodes the low-affinity penicillin-binding protein 2a (PBP2a). Transcriptional regulation of mecA is accomplished in some isolates by mecR1 and mecI, cotranscribed chromosomal genes that encode a putative signal transducer and a transcriptional repressor, respectively. Two Staphylococcus aureus strains that have identical mecR1-mecI nucleotide sequences, BMS1 and N315P, both exhibit low-level, heterotypic expression of methicillin resistance and contain no beta-lactamase coregulatory sequences. mecR1-mecI was amplified from BMS1 by PCR and was shown to be functional on a high-copy-number plasmid when introduced into an S. aureus strain with a deleted mecR1-mecI locus. Cloned mecR1-mecI repressed phenotypic expression of methicillin resistance, mecA transcription and PBP2a production and mediated PBP2a induction in response to certain beta-lactam antibiotics. However, mecR1-mecI had different regulatory activities in its native chromosomal location in N315P compared with those in BMS1. Uninduced mecA transcription was markedly repressed in N315P, and mecI inactivation increased mecA transcription and PBP2a production 5- and 40-fold, respectively. Furthermore, the N315P phenotype changed from low-level, heterotypic resistance with intact mecI to high-level, homotypic resistance in strains with disrupted mecI. In contrast, uninduced BMS1 produced abundant mecA transcript and PBP2a, while the disruption of mecI had no effect on phenotype and little effect on mecA transcription or PBP2a production. Thus, mecI-mediated repression of mecA appears to be dysfunctional in BMS1 because of the presence or absence of additional regulatory cofactors. Furthermore, heterotypic resistance expression in this strain is independent of mecA transcriptional regulation.

Characterization of IS1272, an insertion sequence-like element from Staphylococcus haemolyticus.

We have previously shown (G. L. Archer, D. M. Niemeyer, J. A. Thanassi, and M. J. Pucci, Antimicrob. Agents Chemother. 38:447-454, 1994) that some methicillin-resistant staphylococcal isolates contain a partial deletion of the genes (mecR1 and mecI) that regulate the transcription of the methicillin resistance structural gene (mecA). When a fragment of DNA inserted at the point of the mecR1 deletion was used as a probe, hybridization with multiple bands was detected for Staphylococcus haemolyticus genomic DNA. In the present study, DNA sequencing of four unique clones recovered from a lambda library of S. haemolyticus revealed identical 1,934-bp elements. Each element, designated IS1272, contained 16-bp terminal inverted repeats (sequence identity, 15 of 16 bp) and two open reading frames of 819 and 687 bp; there were no flanking target site duplications. Database searches yielded amino acid homology with proteins predicted to be encoded by open reading frames from a putative insertion sequence element from Enterococcus hirae. DNA probes from each end and the middle of IS1272 were hybridized with restriction endonuclease-digested genomic DNA from clinical S. haemolyticus, Staphylococcus epidermidis, and Staphylococcus aureus isolates. Each of the 20 or more copies of the element found in S. haemolyticus isolates was intact, and copies were found in most chromosomal SmaI fragments. S. aureus and S. epidermidis isolates contained mostly incomplete fragments of the element, and there were many more hybridizing fragments in methicillin-resistant than in methicillin-susceptible isolates. IS1272, which appears to be primarily resident in S. haemolyticus, has disseminated to multiple staphylococcal species and is prevalent in multiresistant isolates.

Regulation of beta-lactamase induction in gram-negative bacteria: a key to understanding the resistance puzzle.

Infections caused by drug-resistant microorganisms have posed a medical challenge since the advent of antimicrobial therapy. With the emergence of resistant strains, new antibiotics were available and introduced with great success until this decade. The appearance of multiresistant microorganisms pose a real and immediate public health concern. Are we entering into the post-antibiotic era? Will we return to pre-antimicrobial-era conditions, with morbidity and mortality resulting from untreatable infectious complications? The race to stay ahead of multiresistance involves not only continued drug development and selective use but elucidation of bacterial regulation of resistance. One way to ensure continued success of antimicrobial therapy is the identification of new bacterial targets--genes and their products involved in regulating or mediating resistance. Discussion will focus on one well-defined resistance mechanism in Gram-negative bacteria, the chromosomally located amp operon, responsible for one mechanism of beta-lactam resistance.

Origin and evolution of DNA associated with resistance to methicillin in staphylococci.

The gene mediating resistance to methicillin in staphylococci (mecA) and its flanking sequences (mec DNA) make up a chromosomal DNA locus that is unique to methicillin-resistant bacteria; no equivalent locus exists in methicillin-susceptible cells. The origin of mec DNA is not known, but evidence supports horizontal transfer of mec DNA between different staphylococcal species and of the mecA gene between different Gram-positive genera.

Dissemination among staphylococci of DNA sequences associated with methicillin resistance.

DNA probes consisting of pUC19 containing cloned Staphylococcus aureus chromosomal fragments were constructed from two methicillin-resistant S. aureus strains with different DNA sequences 5' to mecA, the gene that mediates methicillin resistance. The probe from one strain, BMS1, contained a portion of the regulatory sequences (the terminal 641 bp of mecR1 and all of mecI) associated with the induction and repression of mecA transcription (pGO195). The second probe, from strain COL (pGO198), contained DNA not found in strain BMS1. This DNA was within the sequences added at the site of a mecR1 deletion. Genomic digests of 14 S. aureus isolates recovered between 1961 and 1969 all hybridized with pGO198. In contrast, 78% (36 of 46) of the S. aureus organisms isolated since 1988 hybridized with pGO195 but not with pGO198; the remainder hybridized with pGO198. No S. aureus isolates hybridized with both probes. Staphylococcus epidermidis digests hybridized with pGO198 (46%), pGO195 (14%), or both probes (35%); all 20 Staphylococcus haemolyticus isolates hybridized with pGO198. The restriction fragment length polymorphism patterns of all pGO198-hybridizing regions in S. aureus were identical to those in strain COL. In addition, the mecR1 deletion junction nucleotide sequences of eight S. aureus and six S. epidermidis isolates were identical. However, 21 of 23 S. epidermidis and all 20 S. haemolyticus isolates had from 5 to more than 20 additional chromosomal bands that hybridized with pGO198; none of 21 S. aureus isolates had additional hybridizing bands. These data suggest that the additional DNA responsible for the mecR1 deletion was part of a repetitive, and possibly mobile, element resident in coagulase-negative staphylococci but not in S. aureus. These data also support a hypothesis that the deletion event occurred in a coagulase-negative staphylococcus with subsequent acquisition of the interrupted sequences by S. aureus.