Haemagglutinins have been found in a wide range of organisms. They are capable of agglutinating erythrocytes and other normal or transformed cells, with specific binding characteristics for carbohydrates to produce unique biological activities. We analyzed the haemagglutinating activity of algal extracts from 44 species of freshwater microalgae against native and trypsin/papain - treated cow, pig, sheep, and human A-, B-, and O-type erythrocytes. Algal extracts obtained with aqueous ethanol exhibited higher haemagglutinating activity than those obtained with aqueous acetone. Most of the algal extracts agglutinated at least one of the erythrocyte types analyzed. Human erythrocytes were the most sensitive of the cell types analyzed. In the other species, the sensitivity of algal haemagglutinating activity for erythrocytes was pig > sheep > cow. Pre-treating erythrocytes with trypsin and papain improved the detection of most algal agglutinins and increased the haemagglutination titer; pre-treatment with papain was most effective for pig erythrocytes. Algal extracts stored at –20 oC for four months lost their haemagglutinating activity. Algal extracts were also assayed for antibiotic activity against food pathogen bacteria. We also found that microalgae exhibited strong antibacterial activity against food pathogen bacteria, especially against Bacillus subtilis. Our numerical taxonomy data showed that these microalgae might be grouped into several clusters according to their haemagglutinating activity. Cluster analysis generated four distinct subclusters of taxa, characterized by different specificities for antigens or carbohydrate receptors on the erythrocytes. Principal component analysis further separated the haemagglutination characteristics of Chlamydomonas from Chlorella on the first two components. Specificity for pig erythrocytes accounted for most of the clustering or grouping of algal taxa in multivariate analysis. However, clustering or grouping patterns of Chlorella species on haemagglutinating activity resembled to that on DNA sequences, revealing a possible genetic connection of agglutinins and their biochemical characteristics in algal cells. Agglutinins in microalgae might have evolved through change of specificity with genetic methods. Variability of haemagglutination reactions among the algae investigated is simplified and interpreted most easily using multivariate analysis. Microalgal Chlorella pyrenoidosa were cells cultured, harvested, lyophilized and kept at –20 °C until used for extraction. Crude protein extraction solution was obtained from the powder via several steps including sonicating, centrifuging, precipitating, and dialyzing. We used gel filtration with high resolution Sephacryl S-200 column followed by DEAE-Sepharose procedure for purifying our target hemagglutinin. The purified protein, designated CPH, was a monomeric protein with apparent Mw of 58 kDa on SDS-PAGE and 60 kDa on gel filtration. Hemagglutinating activity of CPH was inhibited with glycoprotein, yeast mannan especially. The amino acid composition was rich in glycine. C. pyrenoidosa was observed with atomic force microscope (AFM) in air condition. The results show that algal morphology was spherical and surface was not smooth. According to the two and tree dimension and detail the morphology of C. pyrenoidosa as spherical shaped with 4-5μm diameters. In opposition, the CPH from C. pyrenoidosa was 20 and 40 nm in width and length, respectively.