Phalaenopsis is an epiphyte native to tropical broadleaf forest in Taiwan. Epiphytic roots attach to the surface of tree trunks instead of growing in soil. Unique structures and morphology of Phalaenopsis roots include velamen outside epidermis, absence of root hairs, lack or absence of branch roots and passage cells in endodermis. Understanding the mechanism of nutrients uptake and metabolism in Phalaenopsis is important to determine how efficient nutrition usage is achieved under intermittent supply. In this study, the growth response and gene expression of Phalaenopsis under N, P, or K deficiency stress were investigated. Phalaenopsis Sogo Yukidian ‘V3’ was grown in a 30/25 oC phytotron and fertilized with solutions containing different concentrations of N (0, 0.71, or 7.14 mM), P (0, 0.16, or 1.6 mM), and K (0, 0.38, or 3.84 mM). Except for lower fresh weight observed in P deficiency treatments, N, P, or K deficiency had little effect on vegetative growth after 8 weeks of treatment, despite lower concentrations of N, P, and K in mature leaves and roots. This shows that Phalaenopsis responds slowly to fertilization. After 8 weeks of treatment in 30/25 °C, plants were transferred to 25/20 °C phytotron to induce spikes. Plants given low N concentration (0.71 mM) had earliest spiking, and required least number of days to 50% spiking (47 days). The SPAD value decreased and the color of the entire foliage of these N-deficient plants turned light green. Phosphorus deficiency delayed spiking where only 33% spiking rate was reached after 80 days of low temperature induction. Purple color was evident on the leaf tips of P-deficient plants. Plants deficient in K required longer to reach 50% spiking (74 days) compared with control (56 days). Yellow spots and necrosis occurred on the upper leaves of these plants after flower opening, and the symptom developed from the tip to the base of the leaves. New leaf growth decreased significantly after spike development in N- and P-deficient plants, but not in K-deficient plants, which had similar new leaf growth rate to plants given full N, P, and K fertilization. After 32 weeks of starvation treatment, significant amounts of N, P, and K were transported to spike and flowers. Because a large amount of nutrients was required for the inflorescence development, the symptoms of nutrition deficiency became evident during the reproductive stage. Microarray analysis revealed differential gene expression in mature leaf and roots during 8 weeks of starvation. There were 794 up-regulated and 129 down-regulated genes commonly appearing in shoots and 101 up- and 89 down-regulated genes in roots under N, P, or K deficiency stress. The transcript levels of DNA and RNA regulation, protein degradation and synthesis, and signaling of receptor kinases were increased in mature leaves. Comparison of the expression of P starvation in Arabidopsis and Phalaenopsis, the phosphate transporter, phosphatase, SQD2 were up-regulated in leaves and roots, and effect on the glycosylglyceride biosynthesis in leaves and roots. Under short-term P starvation, there were no significant symptom in phenotype but the gene regulation already changed. During short-term nutrient starvation, there was regulation of genes for survival in nutrition stress. The PATC128122 was highly up-regulated both in leaf and roots; hence this gene may be used as a marker gene under P starvation.