In our recent paper [Wang and Lee, 2008] (henceforth WL08), we perform an empirical orthogonal function (EOF) analysis on the global annual mean SST over the past 153 years (from 1854 to 2006). The first three EOF modes, which account for 28.3%, 15.3%, and 5.3% of the total variance in the SST data, may represent global warming, ENSO-like (including the Pacific decadal oscillation), and the Atlantic multidecadal oscillation (AMO), respectively. We then use the first EOF mode to study the relationship among global warming, vertical wind shear in the Atlantic hurricane main development region (MDR) and U.S. landfalling hurricanes. The second EOF mode (ENSO-like) and the third EOF mode (the AMO) are presented in another paper (see Figure 1 of Wang et al. [2008a] for these two modes).
 In his comment, Barsugli  (henceforth B09) points out that the SST spatial pattern of the first EOF mode is similar to that of an El Niño event and that its time series contains variations on interannual timescale. He thus concerns that the first EOF mode of global warming may include the interannual ENSO signal and therefore the observed relationship between global warming and U.S. landfalling hurricanes (also vertical wind shear in the hurricane MDR) of WL08 may be partly attributed to interannual ENSO's effect. We appreciate and understand his concern since there is no “perfect” method for separating climate modes on various timescales from observational data such as global warming and ENSO modes. We agree that the first EOF mode contains some interannual variations possibly linked to ENSO and that it is difficult to distinguish anthropogenic climate change from natural low-frequency variability in observational data. However, here we show that the conclusion of WL08 is still true even after removing interannual signals from the first EOF mode. We also present some additional evidences that support the conclusion of WL08.
 B09 suggests that interannual variations are first removed by applying an 11-year running mean to the SST data prior to performing the EOF analysis. We agree that this approach may be a reasonable way to remove the interannual ENSO signal although it still keeps lower-frequency variations of ENSO. We re-perform our EOF analysis following B09's suggestion. The resulting spatial pattern and time series of the first EOF mode are shown in Figures 1a and 1b (Figure 1a is almost identical to Figure 1b of B09), which accounts for 57.4% of the total variance. In comparison with Figure 1 of WL08, the amplitude of SST in the equatorial central Pacific is reduced and the time series is much smoothed. The peaks and valleys in Figure 1b of WL08, which possibly correspond to El Niño and La Niña events (as pointed out by B09), now disappear. This indicates that the first EOF mode in WL08 does contain some interannual variations. However, major features in the spatial pattern and temporal evolution of global warming mode are overall unchanged. In particular, all three tropical oceans are warmed up with a more or less constant warming rate in the 20th century. Figure 1c shows the map of regression coefficient of vertical wind shear onto the time series of Figure 1b. Note that this map of regression coefficient is almost the same as that in Figure 2 of WL08. The large positive and significant (above 95% level) regression still appears in the Atlantic hurricane MDR, suggesting that global warming is associated with an increase of the vertical wind shear, thus inhibits atmospheric convection and disfavors the formation and development of Atlantic hurricanes. Therefore, the conclusion of WL08 is still valid after removing the interannual ENSO signal from the first EOF mode by using the statistical methodology suggested by B09.
 The vertical wind shear in the hurricane MDR does show a secular increase. Using the NCEP-NCAR reanalysis, we calculate the time series of the vertical wind shear in the hurricane MDR during the Atlantic hurricane season of June to November (Figure 2a). In addition to the linear trend (dashed line in Figure 2a), we use two other methods to calculate the secular change of vertical wind shear. Similar to SST analysis, we apply an 11-year running mean to the total vertical wind shear (solid line in Figure 2a). We then project the 11-year running mean time series onto the global warming mode in Figure 1b (bars in Figure 2c). The second method is to first project the 11-year running mean time series onto the AMO signal of Enfield et al.  and then subtract this projection from the 11-year running mean time series (solid line in Figure 2c). All of these calculations show a secular increase (about 2 m/s in 50 years) of the vertical wind shear in the hurricane MDR. It is indicated that as the global ocean is warmed up, the vertical wind shear in the MDR is also secularly increased and thus results in fewer hurricanes, consistent with a weak downward trend observed in U.S. landfalling hurricanes. The main point is that warmings in the tropical Pacific, Indian and Atlantic Oceans compete with one another, producing increased wind shear in the MDR and thus reducing U.S. landfalling hurricanes.
 Our time series of the first EOF mode are consistent with other indices representing global warming observed during the past. For example, the Fourth Assessment Report of the Intergovernmental Panel on Climate Change (IPCC-AR4) uses the annual land-surface air temperature anomalies or the annual combined land-surface air temperature and SST anomalies to show global warming [e.g., Trenberth et al., 2007]. Our indices from the first EOF mode are similar to those of global warming in the IPCC-AR4.
 Finally, the conclusion of WL08 is supported by future model projections under global warming scenarios for the 21st century. By analyzing a suite of coupled ocean-atmosphere model outputs, Vecchi and Soden  report an increase in the vertical wind shear over the Caribbean Sea for future global warming. Our analysis of IPCC-AR4 models (D. B. Enfield et al., unpublished manuscript, 2008) shows that as the Atlantic meridional overturning circulation weakens under future global warming, a cooling effect will cause the North Atlantic to warm more slowly than other oceans (i.e., the Pacific and Indian Oceans) and thus the environment is physically consistent with that under a small Atlantic warm pool. It has been demonstrated that a small Atlantic warm pool enhances the vertical wind shear in the MDR and decreases the moist static instability of the troposphere, both of which disfavor Atlantic hurricane activity [Wang et al., 2008b]. The consistency of our past observational data analysis and the future model projection analyses mentioned above suggests that the increase of the vertical wind shear in the Atlantic hurricane MDR, associated with global warming, is a robust feature.