Improved strategy for molecular genetic diagnostics in juvenile nephronophthisis.

Juvenile or type 1 nephronophthisis (NPH1), an autosomal recessive cystic kidney disease, represents the most common genetic cause of end-stage renal disease in the first two decades of life. Because the disease is caused by large homozygous deletions of the NPHP1 gene in approximately 66% of patients with nephronophthisis, molecular genetic testing offers a method for the definite diagnosis of NPH1 and avoids the invasive procedure of renal biopsy. We recently developed an algorithm for molecular genetic diagnosis of NPH1 that efficiently detects homozygous deletions. However, a major limitation remained for the detection of heterozygous deletions that cause NPH1 in combination with point mutations at the other NPHP1 allele. Because a partial sequence from the NPHP1 region recently became available through the Human Genome Projects, we exploited this information to develop novel polymorphic markers from this genetic region for the detection of heterozygous deletions of NPHP1, thus bridging the diagnostic gap. Five novel polymorphic microsatellites positioned within the large common NPHP1 deletion were generated. Two multiplex polymerase chain reaction sets using two and three polymorphic markers from the NPHP1 deletion region together with one positive control marker allowed four different diagnostic problems to be solved in one diagnostic setup: (1) detection of the classic homozygous deletion of NPH1, (2) detection of a rare smaller homozygous deletion of NPH1, (3) testing for a heterozygous deletion, and (4) potential exclusion of linkage to NPHP1. The newly generated multiplex marker sets will greatly enhance the efficacy of molecular diagnostics in NPH through improved detection of heterozygous deletions.

Establishing an algorithm for molecular genetic diagnostics in 127 families with juvenile nephronophthisis.

BACKGROUND: Juvenile nephronophthisis (NPH1), an autosomal recessive cystic disease of the kidney, represents the most common genetic cause of end-stage renal disease in the first two decades of life. On the basis of identification of the gene (NPHP1) defective in NPH1 and the presence of homozygous deletions of NPHP1 in the majority of NPH1 patients, molecular genetic diagnosis for NPH1 is now possible. Molecular genetic testing offers the only method for definite diagnosis of NPH1 and avoids invasive diagnostic measures like renal biopsy. METHODS: We examined 127 families (204 patients) with the presumed diagnosis of NPH using molecular genetic diagnostic techniques. In 68 families, renal biopsy was performed and was consistent with NPH, and in 61 families, there was more than one affected child ("multiplex families"). RESULTS: In 74 families (115 patients), there was proof of the diagnosis of NPH1 by detection of a homozygous deletion of the NPHP1 gene, and in 5 families a heterozygous deletion in combination with a point mutation in NPHP1 was demonstrated. Furthermore, for 16 families, NPH1 was excluded with high likelihood by linkage analysis, and for 20 families by detection of heterozygosity for two newly identified polymorphic markers within the deletion region. In 5 of the remaining 12 families, which were noninformative for these markers, fluorescence in situ hybridization did not detect any further heterozygous deletions. CONCLUSIONS: The diagnosis of NPH1 was proven by molecular genetic techniques in 62% of families with one or more children with the presumed diagnosis of NPH. We present evidence that there is a fourth locus for NPH, since only 6 of the 26 multiplex families in whom the diagnosis of NPH1 was excluded were compatible with linkage to other loci for NPH. On the basis of the presented data, we propose an algorithm for molecular genetic diagnostics in NPH.

A deletion distinct from the classical homologous recombination of juvenile nephronophthisis type 1 (NPH1) allows exact molecular definition of deletion breakpoints.

Juvenile nephronophthisis, an autosomal recessive cystic kidney disease, is the most common genetic cause of end-stage renal disease in children and young adults. We recently identified by positional cloning the causative gene, NPHP1. Its gene product nephrocystin may play a role in focal adhesion and adherens junction signaling. Approximately 80% of all patients with NPH1 carry large homozygous deletions, which contain the NPHP1 gene. These common deletions are positioned within a complex arrangement of large inverted and direct repeats, suggesting unequal recombination as a potential cause for their origin. In this study we have characterized the deletion breakpoints in a family with juvenile nephronophthisis that bears a unique maternal deletion of the NPHP1 gene, which is not the result of an event of homologous recombination. We molecularly characterized the centromeric and telomeric deletion breakpoints by extensive genomic sequencing, Southern blot analysis, and cloning and sequencing of the junction fragment. We were able to exactly localize the breakpoints at the position of two guanines. The centromeric breakpoint was positioned within intron 2 of the NPHP1 gene 360 bp downstream of the 5' end of a complete LINE-1 element. Multiple topoisomerase I and II consensus sequences were found at the breakpoint sites, suggesting the involvement of topoisomerase II in the deletion mechanism. These findings provide the first data on a potential mechanism for a deletion of the NPHP1 gene, that most likely is not the result of an event of homologous recombination and thereby distinct from the known common deletions.

Fluid resuscitation in circulatory shock.

Over the past century, the treatment of various forms of circulatory shock has included fluid resuscitation with either crystalloidal or colloidal solutions. Despite decades of investigation, there still is considerable controversy over the beneficial and adverse effects of each fluid type. Most authors agree that the initial resuscitation of any form of shock should be performed with crystalloid solutions. Trauma resuscitation uses crystalloid therapy almost exclusively. Much controversy exists when the shock state involves increased microvascular permeability, such as seen in sepsis, anaphylaxis, and burns. Concerns involve increased permeability pulmonary edema and whether colloid or crystalloid therapy may contribute to its formation. Regardless of fluid type used for resuscitative efforts, it is essential to ensure adequate invasive and noninvasive monitoring to guide therapy. Endpoints to resuscitation should include stabilization of vital signs, adequate urine output, adequate cardiac output, and evidence of supply-independent oxygen consumption. Side effects of aggressive fluid loading are frequent and include intravascular volume overload, pulmonary edema, increased myocardial water content, brain swelling, gastrointestinal ischemia, and massive systemic edema. These complications can best be minimized by careful fluid titration, using physiologic and hemodynamic endpoints.

Serotyping and electron microscopy studies of Staphylococcus aureus clinical isolates with monoclonal antibodies to capsular polysaccharide types 5 and 8.

Monoclonal antibodies to Staphylococcus aureus capsular polysaccharide types 5 and 8 were prepared and used to serotype 821 clinical isolates of S. aureus from four countries. The capsular polysaccharide-binding sites on the bacterial membrane were examined by transmission and scanning electron microscopy.

Specificity of H-2-linked Ir gene control in mice: demonstration of T helper cells recognizing branched synthetic polypeptides in low responder mice.

This report provides evidence for the presence of T helper cells capable of recognizing the polypeptide antigens T6-A--L and (H,G)-A--L in low responder mice of H-2k and H-2b haplotypes, respectively. Mice were primed in vivo with the T6-A--L-avidin-(H,G)-A--L complex or, in the case of T6-A--L in H-2k mice, with the cross-reactive and permissive antigen T6-S--L. T helper cells cooperating with DNP-primed B cells could be rechallenged in vitro with the DNP-conjugates of T6--A--L or (H,G)-A--L, although the cells were of low responder type with respect to these antigens. This implies that T cell-macrophage interaction required for restimulation is apparently not defective in these low responders. The implications of these results for the concept of Ir gene control are discussed.