Three closely related alkaline phosphatase (ALP) genes reside on the long arm of chromosome 2 in man. One of these genes (the placental ALP-1) encodes the classic heat-stable placental alkaline phosphatase. Another gene (the placental ALP-2) is closely related to the placental ALP-1 and may encode the so-called placental ALP-like enzyme of the testis and thymus. The third member of this gene family (the intestinal ALP gene) encodes the intestinal alkaline phosphatase. The expression of the placental ALP-1 and intestinal ALP genes is highly tissue-specific in spite of nearly 90% sequence similarity within their exons. To help determine the basis for this tissue specificity, the nucleotide sequence of the placental ALP-1 gene and some of its 5' flanking region has been determined and analyzed by comparison with placental ALP-2 and intestinal ALP gene sequences. The placental ALP-1 gene transcription unit has 4087 bases between the major cap site and the most distal of several reported 3' ends. The protein coding region is divided by 10 short introns varying in size from 74 to 241 nucleotides. Three of these introns bisect regions of the gene that encode residues conserved between the active site of the Escherichia coli enzyme and the human placental ALP. This result suggests that the human alkaline phosphatase genes have evolved in an intron-independent fashion. A comparison of the placental ALP-1 5' flanking sequence (up to -540) with the analogous sequence of the intestinal ALP gene revealed several deletion/substitutions which could be important in determining the tissue-specific expression of these genes.

Alkaline phosphatase (AP) activity is stage specific in mouse embryos and may be associated with compaction and separation of trophectoderm from inner cell mass in preimplantation development. We previously sequenced a cDNA and two mouse AP genes that could contribute to the AP activity in embryos. Oligonucleotide primers were constructed from the three sequences and used in the reverse transcription-polymerase chain reaction technique to establish that two of the three AP isozymes are transcribed during preimplantation development. The predominant transcript (E-AP) is from a gene highly homologous to the human tissue-specific APs, but different from the mouse intestinal AP. Tissue non-specific (TN) AP also is transcribed, but there is approximately 10 times less TN-AP than E-AP transcript. The TN-AP isozyme is the predominant transcript of 7 to 14 day embryos and primordial germ cells. A switch in predominance from E-AP to TN-AP must occur during early postimplantation development. This study establishes a framework for experiments to determine the functions of the two isozymes during preimplantation development.

A phosphatidylinositol-glycan-specific phospholipase D (PI-G PLD) that specifically hydrolyzes the inositol phosphate linkage in proteins anchored by phosphatidylinositol-glycans (PI-Gs) has recently been purified from human and bovine sera. The primary structure of bovine PI-G PLD has now been determined and the functional activity of the enzyme has been studied. Expression of PI-G PLD complementary DNA in COS cells produced a protein that specifically hydrolyzed the inositol phosphate linkage of the PI-G anchor. Cotransfection of PI-G PLD with a PI-G-anchored protein resulted in the secretion of the PI-G-anchored protein. The results suggest that the expression of PI-G PLD may influence the expression and location of PI-G-anchored proteins.