Plants adapt to phosphorus (P) deficiency through a complex of biological processes and many genes are involved. Tomato (Solanum lycopersicum L. ’Hezuo906’) plants were selected to grown hydroponically to study the temporal and spatial gene expression patterns of the 14-3-3 gene family and their roles in response to P deficiency in tomato plants. Using real-time reverse-transcriptase polymerase chain reaction (RT-PCR), we investigated the expression profiles in different tissues (root, stem and leaf) at short-term and long-term P-deficient stress phases. Results revealed that i) four members of 14-3-3 gene family (TFT1, TFT4, TFT6 and TFT7) were involved in the adaptation of tomato plants to P deficiency, ii) TFT7 responded quickly to P deficiency in the root, while TFT6 responded slowly to P deficiency in the leaf, iii) expression response of TFT4 to P-deficient stress was widely distributed in different tissues (root, stem and leaf) while TFT8 only displayed stem-specific expression, and iv) temporal and tissues-specific expression patterns to P deficiency suggested that isoform specificity existed in tomato 14-3-3 gene family. We propose that TFT7 (one member of ε-like group in tomato 14-3-3 family) is the early responsive gene and may play a role in the adaptation of tomato plants to shortterm P deficiency, while TFT6 (one member of non-ε group in tomato 14-3-3 family) is the later responsive gene and may play a role in the adaptation of tomato plants to long-term P deficiency. Plants adapt to phosphorus (P) deficiency through a complex of biological processes and many genes are involved. Tomato (Solanum lycopersicum L. ’Hezuo 906’) plants were selected to grow hydroponically to study the temporal and spatial gene expression patterns of the 14-3 -3 gene family and their roles in response to P deficiency in tomato plants. Using real-time reverse-transcriptase polymerase chain reaction (RT-PCR), we investigated the expression profiles in different tissues (root, stem and leaf) at short- term and long-term P-deficient stress phases. The results showed that i) four members of 14-3-3 gene family (TFT1, TFT4, TFT6 and TFT7) were involved in the adaptation of tomato plants to P deficiency, ii) TFT7 quickly turns to P deficiency in the root while TFT6 only slowly displays P deficiency in the leaf, iii) expression response of TFT4 to P-deficient stress was widely distributed in different tissues (root, stem and leaf) specific expression, and iv) temporal and tissue-specific expression patterns to P deficiency suggested that isoform specificity existed in tomato 14-3-3 gene family. We propose that TFT7 (one member of ε-like group in tomato 14-3-3 family) is the early responsive gene and may play a role in the adaptation of the adaptation of tomato plants to shortterm P deficiency, while TFT6 (one member of non-ε group in tomato 14-3-3 family) is the later responsive gene and may play a role in the adaptation of tomato plants to long-term P deficiency.