Repetitive sequences of the sea urchin genome: Distribution of members of specific repetitive families

Three repetitive sequence families from the sea urchin genome were studied, each defined by homology with a specific cloned probe one to a few hundred nucleotides long. Recombinant λ-sea urchin DNA libraries were screened with these probes, and individual recombinants were selected that include genomic members of these families. Restriction mapping, gel blot, and kinetic analyses were carried out to determine the organization of each repeat family. Sequence elements belonging to the first of the three repeat families were found to be embedded in longer repeat sequences. These repeat sequences frequently occur in small clusters. Members of the second repeat family are also found in a long repetitive sequence environment, but these repeats usually occur singly in any given region of the DNA. The sequences of the third repeat are only 200 to 300 nucleotides long, and are generally terminated by single copy DNA, though a few examples were found associated with other repeats. These three repeat sequence families constitute sets of homologous sequence elements that relate distant regions of the DNA.     

Human hair follicle mites and forensic acarology

The hair follicle mites of the genus Demodex (Demodecidae) were first discovered in humans in 1841. Since then, members of this host-specific genus have been found in 11 of the 18 orders of eutherian mammals with most host species harboring two or more species of Demodex. Humans are host to D. folliculorum and D. brevis. The biology, natural history, and anatomy of these mites as related to their life in the human pilosebaceous complex is reviewed. This information may provide insight into the application of Demodex as a tool for the forensic acarologist/entomologist.     

Popliteal-based filleted lower leg musculocutaneous free-flap coverage of a hemipelvectomy defect.

A 33-year-old man suffered from locally recurrent malignant fibrous histiocytoma of his left thigh unresponsive to previous excision, radiation therapy, chemotherapy, and hyperthermic treatment. He underwent radical hemipelvectomy for cure. Because of extensive tumor involvement, a free flap consisting of his distal left leg based on the popliteal artery was utilized to close the defect. Both the tibia and fibula were removed from their periosteal sheaths, and the foot was excised from the flap. The popliteal artery and vein were anastomosed to the iliac vessels. The flap survived, and the patient was discharged home after physical rehabilitation. We suggest that uninvolved portions of the distal leg may be utilized as a free flap to successfully close hemipelvectomy defects in selected patients when conventional pedicle flaps are unavailable.