Mutants that confer defects in meiotic recombination and synapsis (e.g. zip1) will trigger the pachytene checkpoint to delay and arrest cells at the pachytene stage of meiotic prophase. Previous studies have found that null mutant of yeast heat-shock protein SSA3 can partially suppress the checkpoint-mediated arrest of zip1; moreover, Ssa3 protein is localized to pachytene chromosomes, suggesting Ssa3 may function in the pachytene checkpoint. Here we show that SSA3 is specifically required for the pachytene arrest of zip1, for ssa3 fails to suppress pachytene-arrest of dmc1 mutant, in which the recombination is defective. Pch2, a protein localized to pachytene chromosomes and nucleolus, has been believed that it is involved in the pachytene checkpoint pathway. Using surface-spreading analyses, Ssa3 does not colocalize with Pch2, suggesting that probably Ssa3 does not involved in the Pch2-dependent checkpoint pathway. Ssa3 localizes along the length of pachytene chromosomes, and accumulates in the nucleolus in both wild type and zip1; however, we note that Ssa3 is present in dotty form on pachytene chromosomes in some zip1 mutant. Double staining of Ssa3 and Red1, a prominent component of axial elements/lateral elements of synaptonemal complex (SC), demonstrates that Ssa3 might localize to axial elements/lateral elements of SC. We propose that Ssa3 may provide its chaperon activity for maintaining a proper chromosomal status which is necessary for efficient activation of the pachytene checkpoint in budding yeast. On the other hand, we note that sporulation frequency of pch2 is similar to wild type at 30℃, while it is significantly delayed and reduced at high temperature, 32.5℃, thus we try to investigate the reason. Due to lots of pch2 mutants are arrested at pachytene at high temperature, we use pch2 NDT80-bc mutant to determine whether the pachytene-arrest of pch2 is mediated by the pachytene checkpoint. NDT80-bc is a deletion mutation of NDT80, which completely bypasses the checkpoint. pch2 NDT80-bc displays a wild type-like level and kinetics of sporulation and nuclear division, indicating that high temperature-modulated arrest of pch2 is pachytene checkpoint-mediated. Unlike pch2 mutant, sporulation of zip1 pch2 would not be affected at 32.5℃; as a result, we speculate may be the presence of SC is important for the activation of the pachytene checkpoint in pch2 at high temperature. The zip3 pch2 mutant, which generates partial SCs, is used to compare with zip1 pch2, which generates none of SC. Sporulation frequency and nuclear division of zip3 pch2 is decreased at 32.5℃, suggesting that SCs is required for checkpoint induction in pch2 at high temperature. For these reasons, we propose that high temperature might make SC aberrant in pch2, and the checkpoint signal from aberrant SC is much significant than from absent SC, so pch2 is arrested by the pachytene checkpoint at elevated temperature.